A New Missile Age in Asia
The Indo-Pacific region is at the cusp of a new missile age, driven by perceptions of rising insecurity. Short- to intermediate-range surface-to-surface missile systems are quickly proliferating in the region.1 While military planners and policymakers in the region may view these capabilities as essential to preserving peace and maintaining general deterrence, this proliferation could intensify already complex security dilemmas and heighten nuclear escalation risks in crises.
Contemporary geopolitical dynamics, including systemic competition between China and the United States, and worsening threat perceptions continue to drive substantial investments by regional states in a range of missile capabilities. Other structural shifts have influenced proliferation as well. Notably, after years of alleging Russian noncompliance, the United States left the 1987 Intermediate-Range Nuclear Forces (INF) Treaty in 2019. Washington is now pursuing new ground-launched missiles once again, with a focus on Asia. Action-reaction dynamics between North Korea and South Korea have further accelerated missile proliferation trends. These changes have received insufficient attention by regional policymakers as missile procurement plans have flourished in recent years. Moreover, though the majority of established and emerging missile capabilities in the region are conventional, the potential for these non-nuclear or, in some cases, dual-capable missile systems to intensify nuclear escalation risks has also gone underappreciated. Finally, the complete absence of any regional or subregional mechanisms of negotiated military restraint—never mind formal arms control arrangements—has allowed these trends to continue unabated. Together, these developments are detriments to strategic stability in Asia.
While systematic efforts to assess the risks stemming from missile proliferation in Asia remain limited, headlines from the region in recent years have underscored the drivers and consequences of proliferation. These include China’s firing of ballistic missiles over Taiwan in August 2022, North Korea’s unprecedentedly intense missile-launching campaigns in 2022 and 2023, South Korea’s demonstrations of novel missile capabilities in 2021, Japan’s debate in recent years over whether to procure missiles to hold at risk North Korean targets,2 Australia’s pursuit of long-range strike capabilities under the AUKUS arrangement, and Taiwan’s passing in 2021 of a supplementary defense budget focused on indigenously developed surface-to-surface missile capabilities.3 The United States, too, has stood up several research and development programs for new ground-launched missile capabilities, unencumbered by the erstwhile limitations of the INF Treaty.4 Among these states, missiles are seen as essential for both deterrence and warfighting.
The proliferation of missile capabilities in Asia accompanies a broader surge in regional defense spending since the 2010s (see figures 1 and 2).5 The primary pursuers of significant new missile capabilities in East Asia—Australia, China, Japan, North Korea, South Korea, Taiwan, and the United States—all perceive acute security challenges and see value in long-range strike capabilities for deterrence and conventional warfighting alike. Four of these—Australia, Japan, South Korea, and Taiwan—are U.S. partners, and all but Taiwan are beneficiaries of treaty-codified collective defense arrangements.6 Along with the United States, these partners have particular concerns about China’s regional ambitions and, with the exception of South Korea, are primarily pursuing missile capabilities to deter potential conventional military action against their interests by Beijing. South Korea, which has maintained a robust domestic missile development program since the second half of the Cold War, continues to primarily posture its forces to deter North Korean nuclear and conventional attacks, but over time it could take a more forward-leaning stance against China as well. A permeating, background concern for many of these allies continues to be long-term uncertainty about the reliability of the United States’ extended deterrence commitments—a concern that grew salient in 2017–2021 when former U.S. president Donald Trump sometimes pursued an unorthodox approach to alliances. For these allies, the acquisition of new strike capabilities, while complementary to existing U.S. capabilities in an alliance context, also hedges against an uncertain future.
Amid these drivers, structural conditions in Asia today are not propitious for formal negotiated restraint, including risk reduction, confidence building, and arms control. Unlike the conventional arms buildup that took place in Europe during the Cold War and culminated in negotiated arms reduction processes, the multipolar nature of the contemporary pursuit of missile capabilities in Asia complicates the prospects for ambitious, formal risk reduction and arms control measures. Moreover, the presence of multiple nuclear-armed states with advanced missile capabilities—China, North Korea, the United States, and even India, Pakistan, and Russia—further adds complexity. Finally, unlike the Cold War, the states at the center of contemporary missile proliferation dynamics in Asia do not participate in regional collective defense arrangements like the North Atlantic Treaty Organization (NATO) and the erstwhile Warsaw Pact. While these types of arrangements are not essential to pursuing negotiated restraint, the Cold War condition of bipolarity limited the complexity of potential negotiations. Asia’s multipolar reality today complicates the task of achieving negotiated and verifiable restraint. The United States maintains its traditional hub-and-spoke alliance architecture in Asia through bilateral treaty arrangements with Australia, Japan, and South Korea and more diffuse commitments to Taiwan. While China and North Korea maintain a collective defense arrangement, which was first codified in 1961, their relationship is one of strained alignment7—especially as far as nuclear matters are concerned. Other states in the region pursue varied strategies of alignment, and many seek to preserve their strategic autonomy.
The trend toward missile proliferation in East Asia is unlikely to soon be reversed, but it is imperative that regional decisionmakers fully understand the scope of potential escalation risks and, out of an interest in averting nuclear war, work to limit these risks.
Given these complications, the tractability of missile-focused risk reduction efforts or arms control may appear questionable. While there are substantial obstacles to formalized arms control arrangements in the region, current trends if left unchecked are likely to significantly contribute to escalation risks, including nuclear escalation risks, through multiple pathways. These pathways, discussed in greater detail in the following sections, include, inter alia, preemptive attack postures contributing to first-strike instability, national leadership targeting, and inadvertent escalation through misperceiving the intention behind missile strikes in times of war. Moreover, U.S. policymakers in particular must contend with a regional environment where treaty allies will be increasingly capable of delivering strategic effects on the battlefield with conventional missile capabilities, which could beget a nuclear response from China or North Korea under certain conditions.8 These dynamics demand sustained attention from U.S. and allied policymakers and military planners, who must explore and understand various escalation pathways and further coordinate their operational planning for various contingencies. Finally, the growing variety of missile capabilities could introduce technologically determined sources of escalation risk, including those pertaining to payload ambiguity,9 target ambiguity, and platform ambiguity. National defense establishments in the region have not sufficiently considered these risks as they have pursued missiles as an essential, cost-effective means of projecting power to various ends. To mitigate risks and avert spirals in future crises, policymakers and military planners must first recognize the array of risks and pathways to nuclear escalation that exist. Following this, defense policy processes and military plans can adapt to mitigate unnecessary escalation risks that may stem from existing postures, and regional diplomatic processes can explore negotiated restraint to the fullest extent possible. The trend toward missile proliferation in East Asia is unlikely to soon be reversed, but it is imperative that regional decisionmakers fully understand the scope of potential escalation risks and, out of an interest in averting nuclear war, work to limit these risks.
Conceptual Overview of Missiles
Prior to exploring the drivers of vertical and horizontal proliferation in missile arsenals in the Indo-Pacific, it is essential to first taxonomize and define various surface-attack missile types to understand not only their putative advantages and drawbacks but also how they might contribute to escalation risks in times of crisis or conflict.10 Taxonomizing missiles is far from straightforward in the twenty-first century; traditional distinctions between ballistic missiles and cruise missiles, for instance, are insufficient in describing the contemporary missile landscape. Though technologies such as hypersonic glide vehicles and terminally maneuverable reentry vehicles are not conceptually novel, their proliferation both in Asia and elsewhere means that laying out the distinctions between various missile types can be beneficial for understanding varied risks and their implications.11
Despite the proliferation of complex missile types outside of research and development settings today, it is helpful to identify the fundamental concepts that unify all missile types. These characteristics can be understood as the sine qua non of missiles. At their core, all missile types make use of a chemical rocket booster for propulsion to both accelerate and elevate their payloads, which are weaponized in some form. This use of a weaponized payload, for instance, sets apart ballistic missiles from space launch vehicles (SLVs), which make use of rocket boosters and carry nonweaponized payloads, although large ballistic missiles could be used for space launch and SLVs could be used to carry weapons. Generally speaking (but not in all cases), the physical characteristics of the missile’s booster, including its mass and fuel capacity, are strongly determinative of its range, which for rocket systems in particular varies with the mass of the payload. This payload-booster distinction explains why missiles are sometimes referred to as delivery systems; the object being delivered by the booster at range is the weaponized payload. The incorporation of some form of guidance system further distinguishes missiles from more rudimentary types of rocket-equipped munitions, such as unguided rocket artillery. There are various technologies used to improve guidance capabilities, ranging from the gyroscopic accelerometer systems used in the earliest missiles, like the German V2, to the considerably more advanced computationally assisted, multimodal guidance systems on modern cruise missiles. Most of the contemporary complexity in describing missile types stems from the variety of possibilities concerning payload types. These possibilities are discussed in greater detail later.
Finally, while examining a given missile can spotlight its range and payload capabilities, all missiles in the real world are best understood as part of a broader system. This includes not only the missile itself but also its launcher as well as command-and-control systems, targeting subsystems, and, in the case of certain land-based missiles, fueling and reloading support vehicles.12 Beyond the performance of the missile itself, other characteristics of a missile system can have substantial influence on its military effectiveness and desirability. Solid-propellant missiles, for instance, obviate the need for fueling support vehicles by virtue of having their propellant cast into their airframes during the manufacturing process. With some exceptions, liquid propellant missiles generally require fueling at some point prior to use, rendering them less responsive in a crisis in some cases and potentially more vulnerable to preemption given the more substantial signatures associated with any fueling activity in the field.13
The Basics of Missile Types
Ballistic missiles with ballistic payloads. Ballistic missiles with ballistic payloads are the oldest type of continuously deployed land-attack missiles and among the most widely proliferated land-attack missiles in the world, including in East Asia. They are also the simplest to understand. Essentially, these missiles make use of rocket boosters to accelerate and elevate a payload on a particular azimuth—or direction—that then relies primarily on gravitational force to descend to a target. Apart from gravity, the sole other physical phenomenon influencing the behavior of a payload as it approaches its target after the booster burns out is atmospheric drag upon reentry. Most modern ballistic missiles feature separating reentry vehicles (RVs), which detach from one or more booster stages. (As the term “reentry” implies, the booster separates from the RV outside of the earth’s atmosphere.) These missiles rely on their guidance systems being cued prior to launch and thus are suited for use against known, stationary targets. When launched to long ranges, ballistic payloads reenter the earth’s atmosphere at high speeds. Regardless of the sophistication of their payload type, all missiles launched on a ballistic trajectory are prompt, with RVs arriving at their targets minutes after separation from their boosters. For much of the early missile age, the term “missile” was largely synonymous with “ballistic missile”; this has changed over time as cruise missiles and ballistic missiles using more advanced payloads with aerodynamic and impulsive maneuvering capabilities proliferated. Ballistic payload examples include the North Korean Hwasong-5/6, Russian R-17/Scud-B, and Chinese DF-11.
Ballistic missiles with aerodynamically maneuvering payloads. As mentioned earlier, gravity and atmospheric drag are the two salient physical phenomena that act on missile RVs, influencing their behavior. More advanced missiles often incorporate control surfaces and other physical features that can take advantage of aerodynamic drag to various ends. At the simplest end of the aerodynamically maneuvering payload spectrum are maneuvering reentry vehicles (MaRVs). These payloads use control surfaces to adjust the final trajectory of a separating RV after exoatmospheric ballistic flight to improve their accuracy against a fixed or mobile target and defeat terminal missile defense interceptors. Examples include the North Korean KN21, U.S. Pershing II, and Chinese DF-15.
A second type of aerodynamically maneuvering payload is the unitary aeroballistic (or “quasi-ballistic”) missile. These missiles do not feature separating booster stages—hence, they are “unitary,” combining booster and payload in a single object—and do not necessarily exit the earth’s atmosphere. Instead, the entirety of the missile’s body behaves as an aerodynamic object; after the missile’s booster burns out, the remainder of its flight features unpowered aerodynamic maneuvers. Aeroballistic missiles can behave similarly to MaRVs in their final moments of flight but otherwise glide at high speeds to their targets. Examples include the South Korean Hyunmoo-4, North Korean KN23, U.S. Army Tactical Missile System (ATACMS), and Russian Iskander-M.
A final type of aerodynamically maneuvering payload is the hypersonic glide vehicle (HGV). HGVs are often regarded as a distinct type of hypersonic missile, but they behave according to the same physical principles as other payloads in this category and can be thought of as lying at the far end of a spectrum from MaRVs, which only maneuver in their terminal phase. Like MaRVs, HGV payloads incorporate physical design features to take advantage of aerodynamic lift and drag forces. Also like MaRVs, HGVs separate from booster stages. Unlike MaRVs, however, they reenter the earth’s atmosphere much sooner in their flight trajectories and spend the majority of their total flight time gliding at hypersonic speeds (defined as greater than five times the local speed of sound in a given medium14); in this way, they are also similar to aeroballistic missiles. These shared attributes explain why these three payload types are best understood as part of the same overall capability spectrum. Compared to purely ballistic missiles, however, HGVs can exhibit a longer time-to-target. While HGVs are capable of maneuvering throughout their flight, substantial maneuvers early in an HGV’s flight trajectory will come at the cost of speed and range.15 While the physical principles behind HGVs have been understood for decades,16 advances in materials science and guidance have allowed these systems to become practically deployable weapon systems. HGV payloads endure tremendous thermal and aerodynamic stresses in flight. Beyond this, growing concerns about area and point missile defenses have prompted interest in these capabilities within various military establishments around the world, including in Asia. Examples of HGVs include the Chinese DF-17, U.S. Dark Eagle, and North Korean Hwasong-8.
Ballistic missiles with powered maneuvering payloads. A third distinct category of ballistic payload features active propulsion, either on the RV itself or on a post-boost vehicle. The latter is most commonly associated with multiple independently targetable reentry vehicles (MIRVs) but can also be used to improve the accuracy of a single-RV payload. In the case of MIRVs, the powered “bus” payload carrying the RVs, once separated from its rocket booster stages outside the earth’s atmosphere, maneuvers to orient each warhead toward a distinct target and releases each warhead along its own ballistic trajectory to descend to its target relying primarily on gravitational force. The individual RVs may themselves exhibit other payload characteristics described above (such as terminal maneuvers). MIRVs are not a prominent feature of this report given their primary application in strategic intercontinental missile systems, but shorter-range MIRV capabilities are under development in South Asia by India and Pakistan and were deployed in Europe during the Cold War.
The second form of powered maneuvering payload—and the one more relevant to this report—comprises ballistic missiles designed to strike certain mobile targets, most prominently ships. This new type of missile is less understood in open sources, though it is often covered in news media given its novelty and potential to disrupt the prominence of sea power in the Indo-Pacific. Anti-ship ballistic missiles (ASBMs) likely require both exceptionally advanced RVs that incorporate features consistent with MaRVs and powerful kick motors to allow for rapid error-correction prior to and after reentry to strike mobile targets whose positions may change by hundreds of meters during the missile’s overall flight.17 ASBMs remain a niche capability, and their real-world performance remains uncertain. Examples include the Chinese DF-21D, Chinese DF-26 anti-ship variant, and Iranian Fattah missile.
Land-attack cruise missiles. Land-attack cruise missiles share little in common with the previously described missile and payload types. These missiles fly entirely within the earth’s atmosphere, exhibit powered flight with the use of sustainer propulsion throughout their whole trajectory, and are highly maneuverable. Contemporary long-range cruise missiles are “air-breathing,” meaning that they use the surrounding atmosphere as their oxidizer, increasing fuel efficiency. In many cases, cruise missiles will use a small chemical rocket booster to initiate their air-breathing sustainer engines.18 Their low-altitude flight, high maneuverability, and small size can in combination offer substantial advantages in stressing missile warning systems and defenses, which often detect cruise missiles only as they approach their targets. (Exoatmospheric ballistic missile payloads, by contrast, can be detected by surface radars at longer ranges due to their high altitudes.) While advanced cruise missiles, such as the U.S. Joint Air-to-Surface Standoff Missile (JASSM) and its variants, are considered low-observable munitions, even-more-rudimentary cruise missiles are challenging to track for most states. Traditionally, cruise missiles have been juxtaposed against ballistic missiles as the second major missile type, but the proliferation of nonballistic payloads described above suggests that this dichotomy is no longer appropriate. Most deployed cruise missiles feature turbofan or turbojet engines and fly at subsonic speeds; compared to the time-to-target of ballistic payloads, which are measured in minutes, cruise missiles are generally substantially slower. Advances in sustainer engines have allowed for some states to develop supersonic cruise missiles that incorporate ramjet and/or rocket engines. More advanced cruise missiles in development aspire to hypersonic speeds with the use of supersonic combustion ramjet, or scramjet, engines. These missiles still reach speeds in the relatively low end of hypersonic flight at Mach 5–8. Examples of subsonic cruise missiles include the U.S. Tomahawk, Chinese DF-100, South Korean Hyunmoo-3, and Taiwanese Hsiung Feng IIE; examples of supersonic cruise missiles include the Russian-Indian BrahMos and Chinese YJ-12; an example of a hypersonic cruise missile is the Russian Tsirkon.
Missiles in Modern Warfare
As explained earlier, missiles are, in essence, delivery systems for weaponized payloads at range. For this reason—and with the exception of strategic nuclear missiles designed to range across continents—theater-range missiles of all types are understood to have tactical and strategic effects comparable to those of traditional airpower, albeit with many qualitative advantages over crewed and uncrewed aircraft. Early theoretical examinations of the influence of missiles on modern war—especially in the nuclear age—took airpower theory as their starting point.19 The drivers of missile procurement and proliferation around the world today largely hew to these same principles. Missiles, like airpower and artillery, may not win wars on their own, but they are seen by military establishments and defense policymakers as critical enablers of victory. The difficulty of comprehensive missile defense or defeat—both as a practical matter and in terms of costs—also enhances the perceived deterrence potential of substantial missile arsenals. Deterrence-by-punishment strategies that rely on convincing an adversary of an assured ability to inflict damage are well served by large missile arsenals that cannot be easily or cost-effectively defended against, raising the perceived costs of aggression by an adversary. Many of these same characteristics render missiles the ideal delivery system for nuclear weapons; every nuclear-armed state today relies on missiles as its delivery system of choice, supplemented in some cases by other means of delivery.
Missiles, like airpower and artillery, may not win wars on their own, but they are seen by military establishments and defense policymakers as critical enablers of victory.
The most important qualitative improvement over the course of the missile age has been in precision guidance capabilities. Early missiles, lacking precision, were largely only seen as useful either for the delivery of massively damaging payloads, which could cause damage to their intended targets even if they strayed far off their notional aimpoints, or as weapons of terror against nonmilitary targets, such as cities. Lacking precision, a single missile or a small number of missiles could not be effectively used to achieve tactical effects on the battlefield, especially with conventional warheads. The advent of more precise missiles has significantly improved the value of missiles to modern militaries seeking to achieve tactical and strategic effects at long ranges and with conventional warheads. As this report demonstrates, states with significant conventional missile arsenals—or plans for them—in the Indo-Pacific aspire to use these capabilities to hold at risk a range of military targets to augment strategies of deterrence by denial and deterrence by punishment. Even missile pursuers that largely lacked precise missiles a little more than a decade ago, such as North Korea, have made substantial advances in precision guidance technologies.
The advent and proliferation of precision guidance have made missiles an attractive conventional military capability for many states, but even the most precise missiles depend on substantial enabling factors to prove effective in times of conflict. Robust intelligence, surveillance, and reconnaissance—both in peacetime and in times of conflict—is critical to assessing the location of mobile and fixed targets. Missiles themselves are the final link in the long-range strike kill chain, which depends, as it has for decades, on the ability to find, fix, and finish targets. As missiles proliferate for offensive use, defenders adapt. China and North Korea, for instance, have for many years feared U.S. long-range precision strike capabilities and thus exhibit a strong preference for road-mobile theater-range missile systems, hoping to complicate as much of the kill chain as possible and improve survivability. However, fixed targets, such as known command-and-control nodes and support facilities, remain especially vulnerable and are thus attractive targets for long-range strikes. Defenders, as a result, look to active and passive defenses. (Active defenses comprise missile defense technologies, while passive defenses encompass camouflage, concealment, deception, mobility, and hardening, inter alia.) These measure-countermeasure dynamics are currently at play in the Indo-Pacific and will remain so as missile capabilities continue to proliferate.
In Asia, amid rising geopolitical tensions and a growing assessment by several states that the risk of interstate war is growing, defense budgets have surged, and long-range strike capabilities are almost universally valued. While military planners and policymakers are drawn to missiles due to their many desirable characteristics in augmenting conventional deterrence, they must better understand the risks that accompany rapidly proliferating missile arsenals. Furthermore, regional states are drawn to long-range strike capabilities for differing reasons.
Notes
1 In general, short-range missiles are those with ranges between 300 kilometers and 1,000 kilometers, medium-range missiles are those with ranges between 1,000 kilometers and 3,000 kilometers, and intermediate-range missiles are those with ranges between 3,000 and 5,500 kilometers.
2 Jeffrey W. Hornung, “Is Japan’s Interest in Strike Capabilities a Good Idea?,” War on the Rocks, July 17, 2020, https://warontherocks.com/2020/07/is-japans-interest-in-strike-capabilities-a-good-idea.
3 Kayleigh Madjar, “Lawmakers Pass NT$236.96bn Special Defense Budget,” Taipei Times, January 12, 2022, https://www.taipeitimes.com/News/front/archives/2022/01/12/2003771197.
4 Kingston Reif, “U.S. Aims to Add INF-Range Missiles,” Arms Control Association, October 2020, https://www.armscontrol.org/act/2020-10/news/us-aims-add-inf-range-missiles.
5 Ken Moriyasu, “‘Geopolitical Powder Keg’ Asia Jacks Up Global Military Spending,” Nikkei Asia, August 25, 2022, https://asia.nikkei.com/Politics/International-relations/Indo-Pacific/Geopolitical-powder-keg-Asia-jacks-up-global-military-spending . Time series data on regional defense spending is available from the SIPRI Military Expenditure Database, Stockholm International Peace Research Institute, accessed September 2023, https://www.sipri.org/databases/milex.
6 “U.S. Collective Defense Arrangements,” U.S. Department of State, accessed October 18, 2022, https://2009-2017.state.gov/s/l/treaty/collectivedefense/index.html.
7 Nan Li, “60 Years On, China-North Korea Treaty Still Important for Cooperation and Peace,” NK News, July 11, 2021, https://www.nknews.org/2021/07/60-years-on-china-north-korea-treaty-still-important-for-cooperation-and-peace; and Seong-hyon Lee, “China-N. Korea Defense Treaty,” Korea Times, July 26, 2016, http://www.koreatimes.co.kr/www/opinion/2019/07/197_210355.html.
8 Tong Zhao, “Conventional Long-Range Strike Weapons of US Allies and China’s Concerns of Strategic Instability,” Nonproliferation Review 27, no. 1–3 (January 2, 2020): 109–122, https://doi.org/10.1080/10736700.2020.1795368.
9 James M. Acton, “Is It a Nuke?: Pre-launch Ambiguity and Inadvertent Escalation,” Carnegie Endowment for International Peace, April 9, 2020, https://carnegieendowment.org/2020/04/09/is-it-nuke-pre-launch-ambiguity-and-inadvertent-escalation-pub-81446.
10 This report largely excludes air-to-air, surface-to-air, and anti-ship missiles (with the exception of anti-ship ballistic missiles) because of their tactical roles.
11 Steven T. Dunham and Robert S. Wilson, “The Missile Threat: A Taxonomy for Moving Beyond Ballistic,” Aerospace Corporation, August 2020, https://csps.aerospace.org/sites/default/files/2021-08/Wilson-Dunham_MissileThreat_20200826_0.pdf.
12 Markus Schiller, “Missile Identification and Assessment,” International Institute for Strategic Studies, April 1, 2022, https://www.iiss.org/blogs/research-paper/2022/04/missile-identification-and-assessment.
13 This does not mean that solid-propellant missiles are without undesirable features. Difficulty in casting propellant grain for large missiles, for instance, along with long-term storage and handling difficulties, can make liquid-propellant systems somewhat more reliable for less-experienced missile powers.
14 Within the earth’s atmosphere, the local speed of sound varies primarily with temperature.
15 Cameron L. Tracy and David Wright, “Modelling the Performance of Hypersonic Boost-Glide Missiles,” Science & Global Security 28, no. 3 (2020): 135–170, https://scienceandglobalsecurity.org/archive/2020/12/modelling_the_performance.html.
16 James M. Acton, “Silver Bullet? Asking the Right Questions About Conventional Prompt Global Strike,” Carnegie Endowment for International Peace, September 3, 2013, https://carnegieendowment.org/2013/09/03/silver-bullet-asking-right-questions-about-conventional-prompt-global-strike-pub-52778.
17 Dunham and Wilson, “The Missile Threat: A Taxonomy for Moving Beyond Ballistic,” 15–16.
18 Air-launched cruise missiles may be able to forgo the use of a chemical rocket booster if they are released from an aircraft at sufficient speed to initiate the on-board sustainer engine. This is true of most air-launched cruise missiles in use today.
19 Bernard Brodie, “Strategy in the Missile Age,” RAND Corporation, October 8, 2007, https://www.rand.org/pubs/commercial_books/CB137-1.html.
Regional Missile Arsenals: Strategies and Drivers
General insecurity in the Indo-Pacific has risen in recent years, but the two most likely flash points that could result in a major conflict are the Taiwan Strait and the Korean Peninsula (see map 1). As a result, this report focuses largely on the primary powers implicated in these potential flash points, including China, North Korea, and the United States. Australia, Japan, and South Korea, the preeminent regional U.S. allies, are also significant players. While South Korea has developed a robust arsenal of missiles over decades, both Australia and Japan are quickly adapting to what each perceives as a less secure region.
The regional missile arsenals of other relevant states that could bear on potential crises in the Indo-Pacific—most notably, India and Russia—are not discussed in this chapter due to their limited direct bearing on potential conflicts in the Taiwan Strait or the Korean Peninsula. Both states are discussed in greater detail further in the report; Russia’s role in the lead-up to the collapse of the INF Treaty, in particular, is discussed at length in chapter 3, which focuses more broadly on the United States’ conventional missile development plans for the Indo-Pacific.
General insecurity in the Indo-Pacific has risen in recent years, but the two most likely flash points that could result in a major conflict are the Taiwan Strait and the Korean Peninsula.
China
China possesses a large, diverse, and growing arsenal of nuclear and non-nuclear missiles across all range classes and types. While Chinese missile forces do not outsize those of the United States in all categories, Beijing notably possesses a much larger arsenal of ground-based short-, medium-, and intermediate-range ballistic and cruise missiles than does the United States, which had forgone missiles with a range of 500–5,500 kilometers due to the 1987 INF Treaty. China’s efforts at developing a capable missile force trace their origins to the early Cold War, with the primary motivator initially being the search for a reliable means of long-range nuclear weapons delivery. The Second Artillery Corps of the People’s Liberation Army (PLA), the antecedent organization to today’s PLA Rocket Force (PLARF), was stood up in 1966, two years after China’s first nuclear test. By the 1980s and 1990s, after China had developed and deployed a limited number of large, liquid-propellant strategic missiles capable of ranging the contiguous United States, Beijing embarked on a broader missile modernization effort. Bureaucratic and industrial drivers during that time, rather than a specific, top-down strategic directive, led to rapid growth in China’s missile capabilities—particularly regional missiles.1
The growth of China’s missile forces in the post–Cold War era has further coincided with Beijing’s broader economic growth and concomitant increases in military spending. Moreover, while China’s longer-range missiles during the Cold War were exclusively nuclear, over the last three decades, Beijing has built up a potent force of conventional and dual-capable missiles up through intermediate ranges.2 During the early 1990s, China began to introduce new, short-range missiles, such as the conventional, single-stage, solid-propellant DF-15, to bases in range of Taiwan. An acceleration in the growth of certain classes of Chinese missiles in the late 2010s and early 2020s, such as hypersonic missiles and intermediate-range missiles, has coincided with growing threat perceptions vis-à-vis the United States. While China’s surface-attack missile forces are composed primarily of ballistic missiles, including ballistic missiles with MaRVs, Beijing has also pursued and deployed cruise missiles in land-attack roles.3 Finally, China is the first country to have deployed an operational hypersonic boost-glide vehicle-equipped missile, the DF-17, for a theater mission.4 The contours of Chinese missile forces continue to shift amid a broader military modernization and spending effort to realize, by the centennial of the People’s Republic’s founding in 2049, what Chinese President Xi Jinping has called a “world-class military" (see figure 3).5
Contours of China’s Regional Missile Forces
The majority of Chinese regional missiles are ground launched and operated by the PLARF. Pursuant to military reforms in late 2015, the PLARF was established as a successor to the Second Artillery Corps, the original military organization that was charged with the operation of Chinese missile forces upon its creation in 1966. The PLARF, alongside the PLA Ground Force, PLA Navy, PLA Air Force, and PLA Strategic Support Force, is an independent branch of the Chinese military and reports to the Central Military Commission of the Chinese Communist Party.6 Importantly, the PLARF oversees the totality of China’s ground-based missile forces, including all nuclear-capable missiles up to intercontinental-range ballistic missiles (ICBMs). Of the PLARF’s nine primary organizational subdivisions, known as bases,7 six (Bases 61 through 66) are operational missile units.8 These units vary in their composition: some are composed nearly exclusively of ICBMs (such as Base 66), and others contain a mix of conventional, dual-capable, and theater-range nuclear systems (such as Base 61).9 Each PLARF base is further subdivided into missile brigades.
Two Chinese theater-range, ground-launched missile systems—and a possible third—are dual-capable. One of these—the medium-range family of ballistic missiles known as the DF-21/CH-SS-5—features two exclusively nuclear-armed variants: the DF-21A and another with an unknown Chinese designation (occasionally reported as the DF-21E). Two other variants of the DF-21, including the DF-21C and DF-21D, are conventional. The DF-21A features externally observable differences that distinguish it from the land-attack variant DF-21C and the anti-ship variant DF-21D (discussed in greater detail later). The DF-26 is the second Chinese dual-capable regional system. It is a road-mobile, intermediate-range ballistic missile that can range to the U.S. territory of Guam from most easterly launch points in mainland China. Since it was first deployed in 2016, the overall inventory of available DF-26 launchers has rapidly grown in China. According to the U.S. Department of Defense’s annual estimates, the PLARF operated between sixteen and thirty DF-26 launchers in 2018, eighty in 2019, and two hundred by 2020.10 In 2022, the United States assessed that China possessed approximately 250 DF-26 launchers.11 The DF-26 is unique among all Chinese ground-launched missiles in that its payload is quickly field swappable, allowing for operational units to relatively rapidly switch between conventional and nuclear warheads. This feature has raised particular concerns about prelaunch warhead ambiguity concerning this system.12 Like the DF-21, the DF-26 also has an anti-ship variant. U.S. intelligence leaked in 2023 identified a new missile, designated the DF-27, which is reported to be an HGV-equipped system exhibiting a slightly greater range than the DF-26.13 The third Chinese ground-launched, dual-capable system is the DF-17, the first operationally deployed medium-range HGV-equipped missile system. The DF-17 was revealed at a military parade in 2019, where state media described the system as conventional. Parts of the U.S. intelligence community, however, appear to assess that the DF-17 is dual capable.14
Beyond these dual-capable systems, China possesses a diverse array of short- and medium-range conventional ballistic and cruise missiles that nonetheless could be retrofitted to carry nuclear payloads. These include the short-range DF-15 and DF-16, each of which features multiple variants. Brigades operating both missiles are deployed within range of Taiwan and Japan’s southern Ryukyu Islands (including Okinawa). Notable cruise missile capabilities include two ground-launched cruise missiles (GLCMs): the 1,500-kilometer-range CJ-10/DH-10 and the 2,000-kilometer-range CJ-100/DF-100. China has an active research and development program for hypersonic cruise missiles,15 but no such missiles are known to be deployed. China also operates a variety of ground-launched coastal defense cruise missiles, including the 400-kilometer-range supersonic YJ-12.16
Anti-ship Ballistic Missiles
China has sought to develop ASBMs for more than a decade, with mixed results.17 These capabilities have received disproportionate attention in the United States due to their role in underpinning an anti-access strategy for China that seeks to hold at risk U.S. warships within the first and second island chains (see map 2). To date, it remains uncertain the extent to which China’s ASBM capabilities offer a militarily significant and proven capability. Colloquially dubbed “carrier-killer” missiles, China’s two ASBMs—the DF-21D and a DF-26 variant—were both flight tested against a moving live ship target in the South China Sea for the first time in 2020. Senior U.S. officials confirmed that such a test had taken place, but they did not confirm whether the test successfully demonstrated an ability for the ASBM’s RV to strike the target.18 Since these tests were carried out, further land-based testing of the missiles appeared to be underway, suggesting that the 2020 tests may not have been entirely assessed as successes. For instance, a facility first built in 2019 in the Chinese desert incorporating a mobile target that roughly resembles the dimensions of a U.S. Ford-class aircraft carrier saw renewed activity after the 2020 tests.19 ASBMs represent a formidable technical challenge due to the extremely high levels of precision required to strike a mobile target at sea and the consequent need to quickly update the missile with near-real-time positional data. Given the sustained concern expressed by U.S. analysts and officials about China’s ASBM capabilities, it would appear that these capabilities may have a deterrent effect on the United States in a conflict, even if technical shortcomings may limit performance.
Missiles in Chinese Strategy
Authoritative Chinese texts on military operations, including the 2020 edition of Science of Military Strategy, make multiple references to the roles of missiles in warfare. These include everything from “warning military strikes” with “relatively isolated” effects to large-scale “missile fire assaults” on targets including “reconnaissance and early warning capabilities and command and control capabilities.”20 With regard to long-range conventional missiles, Science of Military Strategy (2020) further underscores their role in carrying out “a certain scale of conventional precision strikes against the enemy’s deep and important strategic targets.”21 The effectiveness of this approach depends on quantitative and qualitative factors, the text notes, including “the number, range, and accuracy of the missiles.”22 The text further underscores that the sufficiency of China’s conventional missile forces depends on quantitative factors more than qualitative ones due to the large number of “strategic and operational” military targets that would need to be held at risk in a local war.23 Overall, missiles are seen as an essential component of pursuing “active defense,” the central strategic guideline of China’s broader defense strategy.24
The primary conflict scenario informing these assessments concerns what Chinese texts refer to as “information-based local war” (or “informatized wars”).25 China’s missile forces are not defined as the primary enabler of victory in such wars but instead are a source of “important support for winning” them.26 This conflict scenario took on prominence in the 2014 strategic guidelines for the PLA, which also emphasized joint operations. China’s 2015 Military Strategy, a defense white paper released by the State Council Information Office, emphasizes the growing role of “long-range precision strikes” for the then PLA Second Artillery Corps.27 Missiles, however, are treated as one among many components of national military power; the 2015 military strategy also emphasizes the role of “maritime military struggle” and the need for China to develop robust naval power.28 Finally, given the Second Artillery Corps’ and the PLARF’s stewardship of China’s land-based strategic nuclear forces, dual-capable medium- and intermediate-range missiles, and conventional missiles, delineations between “theater” and “strategic” strikes are often blurred.
More specialized texts, such as The Science of Second Artillery Campaigns (2004),29 discuss missile operations, strategy, and deterrence in substantially greater detail—particularly as missiles relate to joint military operations. The Science of Second Artillery Campaigns describes long-range precision strike weapons as “an important means and an indispensable operational force in our military’s joint operations for penetrating the enemy’s air defense system, striking the enemy’s in-depth targets, and seizing air and naval dominance in future local wars.”30 It further emphasizes the importance of both qualitative and quantitative factors in achieving strategically significant effects with missiles, underscoring the need to penetrate air and missile defense systems while ensuring sufficiently high levels of precision to achieve “clear strike effects” against a range of military targets.31 PLA analysis of U.S. battlefield successes in the first Gulf War, during which precision-guided munitions featured prominently, prompted greater interest in the enabling role of robust intelligence, surveillance, and reconnaissance capabilities for targeting and damage assessment.32 As Chinese analysts have observed Russia’s large-scale use of nominally precise missiles against Ukrainian targets to relatively limited strategic effect in the Russia-Ukraine War, the importance of robust targeting and enabling technologies has likely been reinforced.
Beyond conventional capabilities, Chinese strategists see nuclear-armed missiles as contributing to general deterrence of conventional war escalation and adversary nuclear coercion, in line with long-standing Chinese concerns about possible nuclear coercion in limited crises, primarily by the United States.33 China continues to adhere to a no-first-use nuclear declaratory policy, first articulated after its initial nuclear test in 1964.34 U.S. analysts and officials routinely express doubt that China would adhere by its declared, no-first-use stance in a crises, however. U.S. analysts have drawn attention to the possibility of large-scale preemptive strikes early in a regional conflict by Chinese conventional missiles, aiming primarily at bases and other critical logistics nodes of a broader U.S. war effort.35 Because of persistent doubts in the United States around China’s no-first-use pledge and its introduction of theater-range, dual-capable missiles, U.S. planners are concerned about the prospect of limited nuclear first use by China.36 The substantial quantitative and qualitative increases in China’s missile arsenal between the mid-1990s and the late 2010s have underpinned these concerns, which remain pervasive and are partly driving ongoing U.S. investments in regional strike capabilities.
Beijing’s vast missile arsenal can project military power all along its periphery, including into disputed waters and islands in the East and South China Seas and, most importantly, into Taiwan.
China’s missile capabilities, however, are not solely directed toward U.S. capabilities and assets in the region. Beijing’s vast missile arsenal can project military power all along its periphery, including into disputed waters and islands in the East and South China Seas and, most importantly, into Taiwan. The central mission for the PLA remains the defense of China’s core interests, which include territorial integrity and sovereignty. As Beijing’s recent defense white papers note, the preeminent warfighting scenario for the PLA remains a conflict over Taiwan. Missiles have featured prominently in Chinese signaling over Taiwan. During the Third Taiwan Strait Crisis in 1995–1996, the Second Artillery Corps carried out two “large-scale conventional deterrence firing exercises,”37 designed to signal Beijing’s ability to inflict damage against Taiwan-based targets. In August 2022, following a visit to the island by then U.S. speaker of the House of Representatives, Nancy Pelosi, the PLARF launched multiple DF-15 missiles around Taiwan, overflying Taipei in the process.38 In April 2023, the PLA claimed that it had simulated strikes on “key targets” in Taiwan; an animation released by official Chinese state media and attributed to the PLA’s Eastern Theater Command showed strikes from mainland-based ballistic and cruise missile units on Taiwanese cities.39 Such strikes would likely be an important enabling component of a broader amphibious invasion campaign.
South Korea
South Korea possesses an advanced conventional missile force that is rapidly evolving. The origins of the country’s indigenous missile development efforts can be traced back to the early 1970s. These initial efforts coincided with the country’s clandestine efforts to pursue nuclear weapons under president Park Chung-hee (1962–1979).40 In the post–Cold War era, South Korea’s Agency for Defense Development has overseen a wide-ranging set of missile development projects. Land-attack missiles have been a prominent focus of these efforts. Beginning with the Lee Myung-bak administration (2008–2013), South Korea’s independent missile capabilities assumed particular prominence in the country’s broader military planning efforts to counter the growing threat from North Korea, the country’s primary, nuclear-armed adversary.41 Under the conservative Park Geun-hye administration (2013–2017), South Korea broadly adapted its pursuit of missile capabilities to a new strategic approach built around three concepts: the Kill Chain, Korea Air and Missile Defense, and Korea Massive Punishment and Retaliation (KMPR). This K3 suite of capabilities has been sustained since, including under the progressive Moon Jae-in administration (2017–2022), which temporarily rebranded each capability.42 The conservative Yoon Suk-yeol administration, which took office in 2022, seeks to establish a new strategic command (K-STRATCOM) by 2024 that will oversee these capabilities.43 The drivers of South Korea’s missile development efforts include deterrence of North Korea, hedging against future uncertainty, and, to a lesser extent for now, interest in buttressing its domestic defense industrial base, overall military power, and regional influence. Some analysts have described Seoul’s broader missile strategy as one of conventional counterforce and damage limitation against North Korea.44
Dwindling Restraint: The U.S.-South Korea Missile Guidelines
An important constraint on South Korea’s indigenous missile capabilities was put in place at the end of the 1970s, amid broader U.S. efforts to ensure that its ally did not develop nuclear weapons after Seoul’s clandestine nuclear program was discovered and terminated. Originally articulated in a classified bilateral understanding between Washington and Seoul in 1979, South Korea agreed not to develop missiles capable of delivering payloads heavier than 500 kilograms to ranges in excess of 180 kilometers in exchange for technical assistance on missile technologies from the United States.45 Over time, these guidelines were repeatedly updated and revised—sometimes in response to advances by North Korea. In 2001, the guidelines were first updated to increase the allowable level of missile development from the original 180 kilometers/500 kilograms to 300 kilometers/500 kilograms, thereby bringing both range and payload limits in line with Missile Technology Control Regime (MTCR) Category I definitions. In 2012, the Lee administration lobbied the administration of U.S. president Barack Obama for further changes to the guidelines following prominent inter-Korean clashes in 2009 and 2010. The 2012 revision, like its 2001 predecessor, further increased the limitation to 800 kilometers/500 kilograms, thereby granting Seoul the ability to, for the first time, pursue missile systems capable of striking any target in North Korean territory from all conceivable launch points in South Korea. In 2017, the quickly advancing North Korean missile threat partially prompted further revisions to these guidelines, with the administration of U.S. president Donald Trump scrapping the payload limitations on South Korean missile development entirely while leaving the range limit of 800 kilometers intact. This was notionally a result of South Korean interest in developing heavy conventional payload missiles that could hold at risk certain deeply buried North Korean targets. Finally, in May 2021, during the first U.S.–South Korea summit meeting after the inauguration of President Joe Biden, the two sides announced that the missile guidelines had been totally scrapped, leaving South Korean missile development efforts fully unconstrained by externally agreed measures of restraint for the first time since 1979.
While range and payload constraints for ballistic missiles had been the primary features of the U.S.-South Korea bilateral missile guidelines, a secondary set of proscriptions limited Seoul’s use of solid propellants for SLVs. A July 2020 modification to the U.S.-South Korea missile guidelines removed these limits entirely, allowing Seoul for the first time to be capable of “developing, producing, and possessing” solid-propellant SLVs.46 Because of common technologies involved in SLVs and long-range missiles, this modification to the guidelines might have generated concerns about a long-range South Korean missile program. But prior changes to the guidelines, including the payload limit removal in 2017, were more consequential to this end and manifested in new South Korean missile capabilities. Instead, Seoul’s interest in solid-fuel SLVs was motivated by the pursuit of more economic launchers for certain types of military reconnaissance satellites destined for low earth orbit. These satellites will have an important role in enabling South Korean military operations against North Korea by improving aggregate intelligence, surveillance, and reconnaissance capabilities available to Seoul. South Korea’s first successful test launch of a solid-fuel SLV took place in March 2022, the same month North Korea carried out its first full-range successful ICBM test on a lofted trajectory since 2017.47 An official South Korean statement underscoring the significance of the SLV test noted that it was a “key milestone” in Seoul’s ongoing efforts to set up a “unilateral space-based surveillance system and bolster defense capability.”48
Drivers of South Korean Missile Development
In the twenty-first century, South Korea’s domestic ground-based missile program has largely focused on the development of precise, conventionally armed, short-range ballistic missiles and a medium-range cruise missile, the Hyunmoo-3. Along with investments in improved intelligence, surveillance, and reconnaissance capabilities, these missile capabilities are primarily envisaged as contributing to the deterrence of North Korean attacks and, should deterrence fail, a range of warfighting objectives. These objectives include, first, limiting damage from North Korean nuclear and conventional missiles and artillery through preemptive and counterbattery strikes and, second, retaliating against the North Korean leadership (including North Korean leader Kim Jong Un) if Pyongyang employs nuclear weapons. These final two objectives were crystallized under the Park Geun-hye administration as the Kill Chain (preemption) and KMPR (decapitation), respectively. These strategies continue to drive South Korea’s investments in missile capabilities and have been sustained by successive governments since.
South Korea’s missile capabilities have qualitatively improved alongside North Korea’s pursuit of ever-more-advanced nuclear and missile capabilities throughout the 2010s. By the end of the 2010s, Seoul’s missile capabilities had come to underpin what two scholars termed a “conventional counterforce” strategy, whereby South Korea was explicitly signaling its intention to destroy its nuclear-armed neighbor’s ability to employ and release nuclear weapons with non-nuclear weapons.49 North Korea, too, has emphasized preemption in its own declaratory doctrine, raising crisis stability concerns on the Korean Peninsula; both countries have strong incentives to shoot first under certain circumstances and increasingly credible missile capabilities to make good on their plans in a crisis. Threats to kill the North Korean leadership, too, raise the risk of nuclear escalation—both deliberate and inadvertent—by Pyongyang.
Despite the apparent stability concerns stemming from both sides’ pursuit of ever-more-advanced conventional missile capabilities, numerous South Korean defense analysts underscore that Seoul’s pursuit of the K3 suite is necessary given the country’s non-nuclear status and the necessity of deterring North Korean attacks.50 Despite its alliance with the United States, Seoul sees ample reason to continue investing in robust autonomous strike capabilities, partly concerned about the long-term reliability of the United States as an ally. Additionally, the United States has been supportive of Seoul’s K3 efforts. While some experts in South Korea may concede that these capabilities could contribute to a heightened risk of escalation with North Korea, they nevertheless underscore the country’s dire strategic environment in justifying Seoul’s investments in strike systems. After North Korea’s openly acknowledged pursuit of tactical nuclear weapons became apparent in 2021, this view has further ossified, particularly under the conservative Yoon administration. Moreover, many policymakers and analysts in Seoul largely reject the logic that South Korea’s capabilities could contribute to a spiral dynamic with North Korea; instead, they assert that effective demonstrations of an ability to preemptively limit damage from Pyongyang’s various conventional and nuclear-capable missile systems (Kill Chain) and an ability to deliver retaliatory strikes against the North Korean leadership (KMPR) will enhance deterrence.
South Korean progressives, who generally favor strategies of engagement toward North Korea, have nevertheless also supported these investments. Former president Moon not only sustained the K3 suite of capabilities but oversaw a substantial increase in defense spending compared to his two conservative predecessors.51 Even as the Moon administration pursed diplomacy with North Korea, South Korea’s defense spending saw year-on-year increases of 7 percent in 2018 and 8.2 percent in 2019 (see figure 4).52 An important driver of this spending was the stated interest of the Moon administration—consistent with earlier progressive administrations—in “the early takeover of wartime operational control.”53 One of the peculiarities of the U.S.–South Korea alliance is that the United States would maintain wartime operational control (OPCON) of the military forces of both sides. The two countries have agreed to transfer wartime operational control to South Korea eventually, but this is now premised on the Conditions Based OPCON Transition Plan. At their forty-sixth Security Consultative Meeting in 2014, the two countries’ defense ministers agreed that the transition would take place when “critical ROK and Alliance military capabilities are secured and the security environment on the Korean Peninsula and the region is conducive to a stable OPCON transition.”54 Seoul’s K3 systems are among the set of capabilities—including broader advances in command, control, communications, and intelligence, surveillance, and reconnaissance—that will be critical to realizing a conditions-based OPCON transfer. South Korean progressives, while generally supportive of the alliance with the United States, seek OPCON transfer as a matter of national sovereignty. Separately, progressive leaders have also emphasized that defense acquisitions should befit South Korea’s geopolitical status, implying that prestige considerations have also been prominent.55 For these reasons, continued investments in autonomous South Korean strike capabilities have persisted despite the presidential transition between conservatives and progressives.
Exports and Long-Term Hedging
Two final factors are prominent drivers of ongoing South Korean investments in missile technologies. The first concerns Seoul’s general ambitions to become a prominent defense exporter. While South Korea is a member of the MTCR and thereby commits—albeit in a politically rather than legally binding manner—to exercise a “strong presumption of denial” concerning transfers of complete longer-range missile systems capable of delivering payloads in excess of 500 kilograms to more than 300 kilometers, its defense industry has otherwise stepped up efforts to develop shorter-range systems that are competitive globally. The K239 Chunmoo, a launcher for sub-MTCR-Category-1-class missiles, for instance, is being procured by the Polish military.56 Seoul has also undertaken efforts to substitute certain imported missile capabilities with indigenous designs that may be partially reverse engineered. A prominent example is a new air-to-ground cruise missile that was first demonstrated by the South Korean Ministry of National Defense in late 2021. That missile physically resembles and appeared to perform similarly to the German-Swedish Taurus KEPD 350K air-launched cruise missile that Seoul first obtained in 2016.57
A final driver of missile investments in Seoul pertains to long-term hedging in an uncertain security environment in Northeast Asia. For instance, in September 2021, South Korea revealed a new supersonic anti-ship cruise missile58—a capability that is far in excess of what would be qualitatively necessary to hold North Korean surface ships at risk. This capability was widely perceived as one that South Korea could bring to bear in a potential future naval clash with China,59 a growing concern for both progressives and conservatives in Seoul, and possibly even with Japan. In September 2021, South Korea also became the first non-nuclear state in the world to develop and test a submarine-launched ballistic missile (SLBM), the Hyunmoo-4-4, and the only state to deploy conventional SLBMs.60 While Seoul’s nominal reason for this capability is to render its KMPR strategy more credible by communicating to Pyongyang that it would have the means to retaliate against North Korea’s leadership even if its ground-launched missile capabilities were destroyed in the course of nuclear strikes, the Hyunmoo-4-4 has raised nuclear hedging concerns. While a conventional SLBM may supplement the KMPR strategy, it would be a natural delivery system for potential nuclear payloads in the future. Amid growing public and elite interest in nuclear weapons acquisition amid North Korea’s quickly advancing missile capabilities,61 Seoul will be well positioned insofar as delivery systems are concerned should it seek to procure nuclear weapons in the future.
North Korea
Although it is among the most resource-constrained states in East Asia, North Korea possesses a formidable array of ballistic and cruise missiles, many of which are capable of delivering nuclear payloads. While the country’s initial efforts at procuring a missile arsenal began with reverse engineering rudimentary Scud-type liquid-fueled ballistic missiles in the late 1970s,62 Pyongyang today possesses ballistic and cruise missiles of all ranges, deliverable via a variety of mobile platforms. Beginning in the mid-2010s, North Korea’s missile capabilities saw substantial qualitative leaps. Between 2015 and 2020, North Korea crossed several important missile development thresholds, demonstrating its first intermediate- and intercontinental-range ballistic missiles, SLBMs, endoatmospheric maneuvering ballistic missiles, and advanced active and passive missile guidance capabilities.63 In January 2021, North Korean leader Kim outlined a wide-ranging set of military modernization objectives at the Eighth Party Congress of the Workers’ Party of Korea, a prominent political event in the North Korean political system.64 The objectives included a substantial focus on regional delivery systems for “tactical” nuclear weapons.65 For example, he called for the development and testing of hypersonic boost-glide systems and long-range cruise missiles, among other capabilities. This military modernization, presented under a broader five-year national plan, remains underway and is expected to last until at least early 2026. North Korea’s missile capabilities—especially in conjunction with nuclear weapons—have contributed sharply to increasing threat perceptions in Japan, South Korea, and the United States. Pyongyang relies on its nuclear forces as an important offset capability to cope with the qualitatively superior conventional forces fielded by the United States and its allies.
Drivers of North Korean Missile Development
A primary driver of North Korea’s missile development efforts over several decades has been its interest in developing a reliable and survivable means of delivery for nuclear weapons. As the world’s newest nuclear-armed state, North Korea has opted for ground-launched, road-mobile ballistic missiles as its preferred mode of delivery for nuclear weapons across all ranges—paralleling its choice for deep conventional strikes. Pyongyang has traditionally justified its pursuit of nuclear weapons as a means of existential insurance against what it perceives as long-standing hostility by the United States. Though the pursuit of credible nuclear deterrence has been the primary driver of North Korea’s missile development efforts more recently, Pyongyang has also put priority on enhanced conventional missile capabilities, primarily with short- and medium-range systems, for warfighting ends below the nuclear threshold if necessary. Indeed, North Korea’s pursuit of missile technology predates its efforts to seek nuclear weapons. However, between the mid-1980s and 2017, North Korean missile flight-testing primarily focused on developing credible strategic nuclear weapons delivery systems; this effort coincided with six nuclear explosive tests conducted between October 2006 and September 2017 and the test launching of long-range missiles of varying designs. In 2017, North Korea for the first time demonstrated on lofted trajectories two types of liquid-propellant-based ICBMs, the Hwasong-14 and the Hwasong-15. Each of these missiles incorporated liquid propellant engines first flight-tested in an intermediate-range ballistic missile, the Hwasong-12.
To offset its long-standing qualitative conventional military disadvantages against U.S. and South Korean forces, North Korea has reserved the right to use nuclear weapons first. A 2013 law, adopted by the country’s Supreme People’s Assembly (a parliament-like body), codified two roles for North Korea’s nuclear weapons: to “deter” general war and, should deterrence fail, “repel” an invasion of its territory. Kim has repeated this framing, including prominently during an April 2022 military parade.66 An update to the 2013 law,67 promulgated in 2022, reaffirmed these roles for nuclear weapons while outlining five sets of conditions under which Pyongyang could resort to the first use of nuclear weapons (see box 1).
Five Conditions for North Korea’s First Use of Nuclear Weapons
North Korean law offers these five conditions (official English translation).
- In case an attack by nuclear weapons or other weapons of mass destruction has been launched or the like is judged to be on the horizon;
- In case a nuclear or non-nuclear attack by hostile forces on the state leadership and the command of the state’s nuclear forces has been launched or to be on the horizon is judged;
- In case a fatal military attack against important strategic objects of the state has launched or the like is judged to be on the horizon;
- In case the operation for preventing the expansion and protraction of a war and taking the initiative in the war is inevitably needed;
- In other case an inevitable situation in which it is compelled to respond by nuclear weapons alone to the catastrophic crisis over the existence of the state and safety of the people is created.
From “Law on DPRK’s Policy on Nuclear Forces Promulgated,” KCNA Watch, September 9, 2022, https://kcnawatch.org/newstream/1662955323-991993754/law-on-dprks-policy-on-nuclear-forces-promulgated.
The conditions, as described in the official English translation of the updated law released by North Korea, are sufficiently expansive to allow for nuclear first use under a range of scenarios. Pyongyang has signaled through its missile tests that it would likely employ nuclear weapons against targets such as ports, airfields, and command and control nodes, to degrade U.S. expeditionary military operations and otherwise blunt the warfighting capability of the U.S.-South Korea alliance. The same updated law in 2022 noted that North Korea would automatically and immediately release its nuclear weapons should its leadership or command and control systems be deliberately attacked.
Dual-Capable Missiles and Tactical Nuclear Weapons
At the Eighth Party Congress of the Workers’ Party of Korea, Kim for the first time declared an intent to develop “tactical” nuclear weapons. No universal definition of tactical nuclear weapons exists, and Kim did not specify what he meant at the time.68 April 2022 was the first time North Korea demonstrated a delivery system that it ascribed a tactical nuclear delivery role to; the tested system was a close-range ballistic missile with a demonstrated range of 110 kilometers. Later that year, North Korea carried out a spate of missile launches that it described as operational exercises for units charged with tactical nuclear operations. These launches featured a spectrum of short-range ballistic missiles, medium-range cruise missiles, and one intermediate-range ballistic missile, suggesting that Pyongyang may be ascribing a tactical role to any missiles capable of ranging targets in the Indo-Pacific theater, including the U.S. territory of Guam (see map 3).
Tactical nuclear weapons in the traditional sense (lower-yield weapons on short-range delivery systems) would be a logical pursuit for a state that has sought to offset its conventional military inferiorities vis-à-vis its adversaries by resorting to credible threats of early nuclear use, as North Korea has. Nevertheless, the pursuit of these weapons, which will broadly coincide with the quantitative growth of North Korea’s strategic nuclear warhead stockpile, introduces new risks. For instance, while North Korea has to date maintained assertive command over its nuclear forces and favored negative controls (for instance, procedures and technical solutions to ensure that nuclear weapons are never used without proper authorization), tactical nuclear weapons are likely to introduce strong incentives for the country’s leadership to consider the delegation of nuclear use authority—if not in peacetime, then in a crisis.69 This, combined with an emphasis on conventional counterforce targeting and potential preemption by Pyongyang’s adversaries, could lead to tremendous incentives to use nuclear weapons early in a crisis. Furthermore, while North Korea is thought to currently store its nuclear warheads at a single site,70 tactical nuclear weapons deployment could lead to incentives to disperse warheads, including at known missile operating bases around the country. Because these bases would likely feature commingled nuclear and conventional missiles and support vehicles, any attacks on such sites could be misperceived by the North Korean leadership as the start of a broader, disarming counterforce strike, generating strong incentives for nuclear use. While North Korea may disperse and conceal its nuclear forces in anticipation of a conventional war, a general lack of strategic situational awareness capabilities would still give Pyongyang reason to fear whether its capabilities would remain sufficiently survivable amid efforts by the United States and its allies to attrite its missile forces. These developments have accelerated efforts in South Korea and, more recently, in Japan to develop plans and capabilities to target North Korean missile launchers and associated infrastructure.
Focus on Survivability and Responsiveness
Trend lines in North Korea’s missile development efforts point to a focus on improving prelaunch and postlaunch survivability and the general responsiveness of its missile forces. These imperatives are a direct result of Pyongyang’s own perceived conventional military weaknesses, its broader lack of strategic situational awareness capabilities, and concerns about the possibility of conventional preemptive attacks by South Korea and the United States (and increasingly Japan). With regard to survivability, Pyongyang has advanced its missile capabilities in several ways. The preponderance of its short-range missile testing since 2017, for instance, has involved solid-propellant missiles. Compared to Pyongyang’s older arsenal of liquid-propellant, Scud-type missiles, these newer missiles are manufactured with the propellant-oxidizer mix cast directly into the airframe, obviating the need for fueling prior to launch. This reduces the need for supporting fueling vehicles, thereby decreasing the signature of field-deployed mobile missile units on overhead optical satellites, and simultaneously removes the need for a missile to remain stationary while being fueled, which makes them vulnerable to a preemptive strike if detected. North Korea has also started to base short-range missiles on rail-mobile launchers and emphasized the promptness of its ability to launch missiles in a crisis.
Trend lines in North Korea’s missile development efforts point to a focus on improving prelaunch and postlaunch survivability and the general responsiveness of its missile forces.
To further improve prelaunch survivability, North Korea has started to manufacture at scale tracked chassis missile launchers that are capable of carrying out launches from unpaved roads and entirely off-road locations. This ostensibly complicates tracking and targeting for its adversaries, who can no longer rely on tracking missile launchers along the relatively modest paved road networks in the country. Pyongyang has also expanded its extensive network of underground facilities, tunnels, and drive-through missile shelters to complicate adversary tracking of its mobile missile launchers. In 2022, North Korea also indicated that it would begin basing certain missiles in inland lakes, though its actual adoption of such a basing mode has yet to be confirmed.71
A second set of survivability improvements concerns the defeat of U.S. and allied missile defense capabilities. While the quantitative expansion of North Korea’s missile forces poses a significant challenge for U.S. and allied theater missile defense capabilities, which are at risk of being overwhelmed with saturation strikes and salvo attacks, Pyongyang is also investing in qualitative means of stressing and defeating missile defenses. Efforts in this area have included investments in maneuvering missile payloads, including HGVs, MaRVs, and cruise missiles. North Korea has also devoted particular attention to endoatmospheric, aeroballistic short-range ballistic missiles that may exploit a perceived gap between the altitudinal limits of certain types of missile defense interceptors known to have been deployed on South Korean soil.72 These investments are, in part, a response to sustained investment in missile defense capabilities by Japan, South Korea, and the United States.
Australia
Australia has not traditionally sought or maintained long-range precision strike missile capabilities, but this has begun to change. Intensifying threat perceptions concerning China have been a primary driver of greater Australian interest in procuring advanced missile capabilities as part of a broader strategic adjustment in the country’s defense policy toward the twin objectives of assuring territorial defense while maintaining a power projection capability. The shifting approach to defense policymaking in Canberra is best seen in the changes that resulted between the country’s 2016 Defence White Paper73 and its 2020 Defence Strategic Update,74 the latter of which recognized a growing “risk of state-on-state conflict” and articulated a need for Australia to pursue a force capable of “[projecting] military power to shape our environment, deter actions against [Australian] interests and, when required, respond with effective military force.” These aspirations were further refined in Australia’s 2023 Defence Strategic Review.75 While Australian defense spending over the last decade has remained within 1.7 and 2.0 percent of gross domestic product (GDP), it has grown in absolute terms (see figure 5).76
Pursuant to the 1951 Australia, New Zealand, and United States Security Treaty (ANZUS Treaty), Australia is party to a collective defense arrangement with the United States and, as a result, maintains close interoperability and consultations with Washington on defense matters.77 In 2011, as the Obama administration’s pivot to Asia was beginning to take shape, Australia and the United States announced a series of Force Posture Initiatives, which were codified in a bilateral treaty in 2014.78 Pursuant to the treaty, the two sides established a bilateral Force Posture Working Group to coordinate activities and advance cooperation on a range of matters. In September 2021, Australia, the United Kingdom, and the United States announced a trilateral defense-industrial partnership known as AUKUS that includes plans for cooperation on defense technologies.79 While much attention has focused on how the AUKUS partnership gives Australia the capability to operate nuclear-powered attack submarines, it also includes considerable provisions to facilitate the procurement and indigenous production of long-range strike systems, including hypersonic weapons.80
Accelerating Readiness
In April 2022, the government of former Australian prime minister Scott Morrison approved a plan for 3.5 billion Australian dollars ($2.2 billion) to accelerate the “acquisition of improved weapon capabilities for the Australian Defence Force.”81 Pursuant to the 2020 Defence Strategic Update, the specific missile capabilities this sought to fund included the U.S.-made 1,000-kilometer-range Joint Air-to-Surface Standoff Missile Extended Range (JASSM-ER); its anti-ship version, the 370-kilometer Long-Range Anti-Ship Missile (LRASM); and the dual-mode (anti-ship and land-attack), 250-kilometer Naval Strike Missile (NSM). Peter Dutton, the former Australian defense minister, said at the time that these investments were necessary for Australia due to changes in the strategic environment, requiring the Australian Defence Force to “be able to hold potential adversary forces and infrastructure at risk from a greater distance.”82 JASSM-ER/LRASM will arm the Australian FA-18F Super Hornet fighter aircraft and, eventually, the F-35A Lightning II fighter aircraft. The NSM will replace existing Harpoon anti-ship missiles on ANZAC-class frigates and Hobart-class destroyers. The Australian Department of Defence notes that the NSM would represent a “significant enhancement” of capability over the Harpoon due to the fact that it would “more than [double] the current maritime strike range of our frigates and destroyers.” Australia will also purchase U.S.-made 1,600+ kilometer Tomahawk Block IV and Block V land-attack cruise missiles for its Hobart-class destroyers, enabling its “maritime assets to strike land targets at greater distances, with better precision.”83
Finally, Canberra seeks new land-based precision strike missiles, which will be tasked with “destroying, neutralising and supressing [sic] diverse targets from over 400 km.”84 This requirement will be met by current and future increments of the U.S.-made Precision Strike Missile (PrSM). Australia’s 2020 Defence Strategic Update also notes that the country will seek “self-reliant geospatial-information and intelligence capability,” in part to “support precision guided weapons.”85 Despite a political transition in 2022 from a Liberal Party government to a Labor Party one under Prime Minister Anthony Albanese, Australia’s broader defense orientation has remained unchanged—as has Canberra’s enthusiasm for coordinating with the United Kingdom and the United States under the AUKUS arrangement.
Apart from its own investments in long-range strike capabilities, Australia is substantially enhancing its bilateral cooperation with the United States under the Force Posture Initiatives. A particularly notable initiative in this area is a bilateral plan to support new U.S. long-range bomber support facilities in northern Australia, the establishment of which has been ongoing since 2020. (U.S. bombers have trained with the Royal Australian Air Force and spent more time deployed to Australian bases.86) Australia’s strategic location in the Indo-Pacific has been a particular draw for the United States, which has attempted to improve the survivability of its forward-deployed bomber forces in Asia by seeking additional basing facilities beyond those available in Guam and Hawaii in the Pacific and Diego Garcia in the Indian Ocean. New and dedicated facilities in Australia to fuel bombers, maintain conventional munitions stocks, conduct maintenance, and house personnel would improve the flexibility of U.S. bomber operations in the Indo-Pacific. Notably, unlike the U.S. territory of Guam, the city of Darwin in northern Australia likely falls out of the range of Chinese ground-launched, theater-range strike systems such as the DF-26 intermediate-range ballistic missile. Australia’s geographic advantage may be blunted as China proceeds to develop potentially longer-range conventional strike systems, nearing if not exceeding the traditional intercontinental-range threshold of 5,500 kilometers, but Australian and U.S. military planners may believe that the added targeting requirements for China may enhance general deterrence.
New and dedicated facilities in Australia to fuel bombers, maintain conventional munitions stocks, conduct maintenance, and house personnel would improve the flexibility of U.S. bomber operations in the Indo-Pacific.
Under AUKUS specifically, Australia, the United Kingdom, and the United States are planning to initiate new forms of defense-industrial cooperation on hypersonic missiles, though in September 2023 specifics remained sparse. Cooperation in this area between Washington and Canberra dates back to the late 2000s, when Australia’s Defence Science and Technology Group and the U.S. Air Force Research Laboratory began collaborating through the Hypersonic International Flight Research Experimentation (HIFiRE) program. HIFiRE, which also included the U.S. National Aeronautics and Space Administration at one point, was not explicitly oriented around missile development, however, and focused generally on the applicability of hypersonic bodies for “next generation aeronautical systems.”87 Building on HIFiRE, the two countries announced the Southern Cross Integrated Flight Research Experiment (SCIFiRE) initiative in 2020, focused on developing air-breathing hypersonic technologies.88 (HIFiRE saw limited experimentation with scramjet technologies.89) Testing pursuant to these programs has taken place at Australia’s Woomera test range in the country’s south.90
An April 2022 summit statement by the three AUKUS leaders noted that they have committed to “commence new trilateral cooperation on hypersonics and counter-hypersonics.”91 While the United States is considerably more advanced among the three partners insofar as research and development for hypersonic missiles is concerned, Australia has developed a substantial base of independent scientific and technical talent in this area since the 2010s and operates seven hypersonic wind tunnels. A trilateral AUKUS hypersonic missile program may still be derived from existing or planned U.S. systems, however. Following the collapse of the 1987 INF Treaty, the United States has accelerated efforts to develop and deploy new theater-range hypersonic missiles. Apart from hypersonic missiles, Australia has committed resources to at least one such U.S. “post-INF” missile system; Canberra, under the Morrison government, committed funds to codevelop a new increment of the U.S. Army’s PrSM.92 This agreement was cinched the month before AUKUS was formally announced in September 2021, indicating that U.S.-Australia cooperative activities on joint missile development predated the newer flagship trilateral partnership.
A final notable component of Australia’s future plans related to missiles—though not necessarily long-range missiles—concerns the 2020 Defense Strategic Update’s defense enterprise goals.93 Specifically, Canberra has started the process of establishing a sovereign capability to manufacture advanced, guided weapons and explosive ordnance. After the announcement of the AUKUS partnership, Canberra further accelerated 1 billion Australian dollars ($640 million) for this sovereign enterprise capability. An additional 1.5 billion Australian dollars ($960 million) was announced for this purpose in 2023. The strategic logic driving this investment concerns Australia’s vulnerability to outside suppliers and partners to sustain its stocks of munitions that could be quickly expended in a high-intensity interstate conventional war. To mitigate these vulnerabilities, the country is working to establish a sovereign capability to quickly replenish munitions stocks. Over the long term, this sovereign manufacturing capability, combined with Canberra’s expanding talent and knowledge base, could enable the manufacture of new long-range missiles. According to Australian officials involved with the Sovereign Guided Weapons and Explosive Ordnance (GWEO) Enterprise, this initiative will remain highly dependent on access to intellectual property and data from the United States, which is not assured but may be more likely pursuant to the AUKUS partnership.94 Australian officials have also cited the intensity of munitions requirements observed in the Russia-Ukraine war as another motivator for continuing investments in GWEO.95
Japan
Among the U.S. treaty allies examined in this study, Japan is unique in its constitutional constraints on pursuing certain military capabilities. The country’s constitution, drafted under U.S. occupation in the aftermath of World War II, saw Tokyo “forever renounce war” as a means of pursuing its national interests.96 Article Nine of the constitution proscribes Tokyo’s pursuit of “war potential” and forswears the “right of belligerency.” While the precise meaning of Article Nine has been reinterpreted to allow for the gradual expansion of Japan’s defense capabilities and for Tokyo to play a more active—and even expeditionary—role within the context of the U.S.-Japan treaty alliance, these constitutional restraints have continued to influence debates in Japan on the types of capabilities that the country can legally procure. The dominant Liberal Democratic Party (LDP), which has ruled Japan for most of its postwar history, has seen prominent political leaders seek to reinterpret these constitutional restraints in pursuit of something akin to a normalized defense posture. The late prime minister Abe Shinzo was among the most prominent of these leaders; as Japan’s longest-serving postwar prime minister over two nonconsecutive terms, Abe oversaw substantial changes to Japan’s defense posture. Abe’s second stint, from December 2012 to September 2020, saw military reforms, defense white papers that articulated Tokyo’s threat perceptions vis-à-vis China in no uncertain terms, and prominent adjustments to the defense guidelines that underpin the U.S.-Japan alliance.97 In the aftermath of Russia’s 2022 invasion of Ukraine and amid sharply rising threat perceptions in Tokyo concerning both China and North Korea, Tokyo promulgated an updated National Security Strategy and a National Defense Strategy that represent nothing short of a sea change in postwar Japanese defense policy and plans.
Long-range land-attack missiles, by their very nature, are generally seen as offensive capabilities, designed to destroy targets at range. As a result, they traditionally have been deemed as incompatible with Japan’s constitutional constraints. A common analogy used to describe the role of Japan’s military capabilities in the context of its alliance with the United States was to juxtapose Tokyo’s capabilities as the “shield” to Washington’s “spear.” In other words, Japan would pursue exclusively defensive capabilities while enabling U.S. expeditionary military operations in Northeast Asia.98 Japanese officials note, however, that this was due to a policy choice by Tokyo and not a legal determination. Therefore, Tokyo’s landmark 2022 National Security Strategy was able to endorse a call for new, longer-range missile capabilities to hold at risk adversary missile launchers and related infrastructure. In the post–Cold War era, legislative changes opened the door for Japan’s Self-Defense Forces to join United Nations peacekeeping operations overseas and support U.S. forces in Afghanistan and Iraq.
The primary drivers of Japan’s move toward openly pursuing long-range strike capabilities in the 2020s are growing geopolitical friction with China and serious concerns about the threat posed by North Korea’s increasingly sophisticated and large nuclear and conventional missile forces. The latter was explicitly centered in Japanese debates in the late 2010s and early 2020s on acquiring long-range strike capabilities, but concerns about China have also driven interest. For instance, Japan has moved anti-ship and anti-air missiles to four islands along its southwestern Ryukyu chain to contribute to the defense of the Senkaku Islands, which Tokyo administers but Beijing claims and calls the Diaoyu Islands. Some of these capabilities may also contribute to a Taiwan contingency,99 which is increasingly driving Japanese defense policy and featured prominently in the domestic debates leading up to the 2022 revised National Security Strategy. The United States is also involved in augmenting strike operations along the Ryukyu Islands;100 a new U.S. marine littoral regiment will become operational in the region by the mid-2020s and will field uncrewed Navy Marine Expeditionary Ship Interdiction System (NMESIS) launchers armed with NSMs.101 The regiment will deploy initially on Okinawa but may expand to other islands.102
A Debate on “Strike” Capabilities
Japan began to consider the security consequences of North Korea’s burgeoning missile programs in the early 1990s. The real wake-up call for Tokyo came in 1998, when Pyongyang flew the Taepodong-1 satellite launch technology demonstrator over Japan. The overflight precipitated a sharp interest in Tokyo in missile defense. Following that demonstration, Japan and the United States began to cooperate with unprecedented closeness in developing missile defense interceptors and systems, including the SM-3 Cooperative Development Project to develop the SM-3 Block IIA variant interceptor. Faced with a growing missile threat in its neighborhood and nevertheless constrained by its constitution, Japan largely looked to missile defenses as a solution. In 2017, unprecedented qualitative breakthroughs from North Korea further shocked Japan. In August and September that year, Pyongyang flew intermediate-range Hwasong-12 ballistic missiles over Japan, marking the first time Japanese territory had been overflown with missiles explicitly characterized as designed to carry nuclear weapons. These launches prompted a serious study in Japan of whether its existing missile defense architecture, which by then had grown to include a range of capabilities on land and at sea, was fit for the task of managing North Korea’s evolving missile arsenal. In December 2017, the Abe administration finalized plans to pursue two fixed Aegis Ashore missile defense sites that could add to Tokyo’s existing missile defense coverage.103 After domestic political difficulties concerning the locations of these sites and public concerns about the consequences of spent interceptor stages potentially landing on populated Japanese territory, the Abe administration canceled these deployment plans in June 2020.104 The overall costs of the system—and of missile defense in general as a long-term plan for coping with the threat posed by North Korean missiles—also factored into government decisionmaking in the lead-up to the decision to scrap the two sites.105
As the plan to deploy Aegis Ashore sites moved forward between 2017 and 2020, parts of the LDP were counseling the Abe administration to consider alternatives to missile defense, namely strike capabilities. As early as March 2017, prominent LDP members, citing a “new level of threat” from North Korea, prompted Abe to consider Japan’s pursuit of “our own capability of striking back at an enemy base, with cruise missiles for instance, to further improve deterrence and response as part of the Japan-U.S. alliance.”106 Onodera Itsunori, who from 2012 to 2014 served as Abe’s first defense minister during his second nonconsecutive prime ministerial term, led that intra-LDP council. Onodera served again as Abe’s defense minister from 2017 to 2018, overseeing the final decision to move ahead with Aegis Ashore.107 Following the cancellation of the Aegis Ashore procurement plan in June 2020, Abe requested that Onodera lead another LDP policy committee to study alternative missile defeat plans, including the strike capability idea that the former defense minister had championed in early 2017. Like in early 2017, the committee returned with a recommendation to seek long-range strike capabilities: “Our country needs to consider ways to strengthen deterrence, including having the capability to halt ballistic missile attacks within the territory of our adversaries,” the proposal document said.108 The committee was careful in its choice of verb, opting for the considerably neutral “halt” and eschewing terms that could imply offensive intent, such as “attack.” The constitutionality matter was largely treated as settled within the LDP, as long as the intent was to forestall an “imminent” attack. The precedent here was a 1956 statement by former Japanese prime minister Hatoyama Ichiro, who had once said that Japan could take “minimum measures unavoidably necessary,” when no other means were available, to forestall an “imminent illegal invasion.”109 Speaking before the Diet, Japan’s bicameral legislature, Hatoyama also expressed the view that “I cannot believe that it is the constitution’s intention for us to sit and wait for our own destruction.” Between Hatoyama’s 1956 statements and the 2020 Onodera committee recommendations, several private government-commissioned studies and remarks by public figures, including Abe, hinted at long-running interest in Japan in acquiring such capabilities—even prior to North Korea’s first nuclear test in October 2006.110
These Japanese debates, particularly between 2017 and 2022, were often presented in international media as concerning a “strike capability.” Officially, Japanese experts and politicians preferred to allude to a “counter-attack capability” (or counter-strike capability), implicitly indicating that Tokyo would only seek to carry out deep strikes against an adversary’s territory once an attack on Japan was underway. This would nominally foreclose the possibility of preemptive attacks, whereby Japan would launch strikes prior to actually suffering an adversary’s strikes. As the plans proceeded in 2022, amid Prime Minister Kishida Fumio’s efforts to update Japan’s National Security Strategy and National Defense Strategy, the LDP addressed this issue with its more restrained coalition partner, the Komeito party. October 2022 consultations between the two parties, however, revealed reluctance on the part of the LDP to fully clarify the Japanese government’s interpretation of what the initiation of an adversary’s attack might mean—with the intention of augmenting deterrence through manifesting ambiguity in an adversary’s decisionmaking calculus.111 Komeito, however, sought to limit the range of scenarios in which Japan could carry out strikes as well as the targets of such strikes. A notable divergence between the two concerned whether “command and control functions” should be acceptable targets for Japanese strikes.112 The final 2022 National Security Strategy and National Defense Strategy leave this matter explicitly unaddressed, preserving a certain degree of ambiguity that may be deliberate.
Notably, Japan’s internal debates on acquiring these capabilities accelerated largely in parallel to the disintegration of the INF Treaty (discussed in a subsequent chapter). Despite the possibility of a newly unconstrained U.S. missile arsenal becoming available for basing on Japanese soil at some point in the mid-to-late 2020s, Japanese defense experts and officials appeared to favor an independent capability, with some seeing a compelling military logic to Japan’s possession of such weapons and others simply seeing U.S. missiles on Japanese soil as a bridge too far, politically speaking.113 During the Abe-era consultations on missile defeat strategies, including missile defense and strike capabilities, prominent Japanese defense officials indicated that Tokyo should be prepared to hedge against an uncertain future—both in terms of regional threat perceptions and in terms of the U.S.-Japan alliance—by building capabilities that would allow it to, in effect, limit damage and attrite an adversary’s missile forces with long-range strike weapons of its own.114 The acquisition of such capabilities could not only augment deterrence of attacks on Japanese territory but also limit the scope of damage to Japan if deterrence failed. Furthermore, Japanese officials appeared to believe that such capabilities would be largely complementary to U.S. expeditionary and strike capabilities in the region, including possible conventional missile systems that the United States might deploy to Asia in the aftermath of the INF Treaty. Finally, though rarely expressed in public, Japanese officials bore concerns about the reliability of the United States as an ally—particularly under Trump’s erratic presidency between 2017 and 2021. In the course of 2020 debates on Japan’s strike capability, Nakatani Gen, a former LDP defense minister, alluded to these concerns, noting that Tokyo “cannot take for granted that the United States will retaliate if we are attacked,” and consequently Japan must “enhance deterrence by developing our own retaliatory capability.”115
Pursuit of New Capabilities
Despite its constitutional constraints, Japan does possess notable missile capabilities—although none that were deployed as of October 2023 were capable of carrying out deep strikes on targets within China or North Korea from Japanese territory. The most prominent indigenous, ground-based Japanese missile system is the 180-kilometer-range Type 88/SSM-1 anti-ship cruise missile system. The Type 12, an improvement to the Type 88, was introduced in 2015 and features an advanced guidance package and greater precision alongside a modest range extension to 200 kilometers. Press reports prior to the finalization of the Kishida administration’s National Security Strategy suggested that the Japanese Ministry of Defense planned to authorize research, development, testing, and evaluation of longer-range land-attack variants of the Type 12, with the ceiling on possible range extensions surpassing 1,000 kilometers.116 This was ultimately endorsed by the government, but the technical work necessary to extend the range of these missiles may take until early 2026.117 Japan’s 2021 defense budget included 33.5 billion yen ($306 million in 2021 U.S. dollars) for the development of an extended-range Type 12 variant.118 Press reports have also underscored that the Japanese Ministry of Defense is exploring the possibility of developing hypersonic land-attack missiles capable of holding at risk targets up to 3,000 kilometers away, which would allow deep strikes into much of mainland China.119 If based on Ishigaki Island, which is 400 kilometers southwest of Okinawa on the first island chain, such missiles would be able to range all known PLARF brigades with the exception of Brigade 646 in Xinjiang and China’s new fixed ICBM silo fields. These missiles, if pursued, are to be developed by the mid-2030s. Range extension efforts will likely be paired with efforts to base these cruise missiles on new launch platforms, including fighter aircraft and surface ships of the Japan Maritime Self-Defense Force.120 Tokyo is also likely to explore the emplacement of long-range cruise missiles on submarines.121 The Japanese government has earmarked 5 trillion yen ($37 billion in 2022 U.S. dollars) for the procurement of new long-range missiles between the 2023 and 2027 fiscal years.122 Japanese analysts who support these efforts underscore trends in regional missile proliferation in Northeast Asia, particularly the rapid growth of Chinese, North Korean, and even South Korean missiles capable of ranging in excess of a few hundred kilometers.123 Beyond its indigenous capabilities, Japan’s 2018 National Defense Program Guidelines and Medium Term Defense Program endorsed the procurement of the U.S.-made JASSM/LRASM air-launched cruise missiles and the Norwegian-U.S.-made air-launched Joint Strike Missile.124
The United States recently has been supportive of Japanese efforts to acquire long-range strike capabilities.
The United States recently has been supportive of Japanese efforts to acquire long-range strike capabilities. Within the confines of the alliance, Japan’s missile capabilities are being increasingly integrated with U.S. airpower. For instance, the two sides have carried out joint exercises to study how Japanese anti-ship missile units in the first island chain could create a favorable operational environment for U.S. airpower.125 In the aftermath of the United States leaving the INF Treaty, some U.S. officials also encouraged Tokyo to potentially host or procure new U.S. missiles. Marshall Billingslea, the former U.S. presidential envoy for arms control in the Trump administration, for instance, described the U.S. Tomahawk land-attack cruise missile as “exactly the kind of defensive capability that countries such as Japan will want and will need for the future.”126 While the United States and Japan did not formally consult on the basing of U.S. missiles on Japanese soil immediately after the INF Treaty disintegrated, Trump administration officials raised the issue, underscoring in particular China’s growing missile capabilities.127 Despite that, since the end of the INF Treaty, Japan’s determination to buttress its own strike capabilities has only expanded—with little added interest in the possibility of hosting U.S. missiles.128 Procuring U.S. missiles, however, is part of Tokyo’s plans. As part of its broader defense spending outlays through the 2027 fiscal year (see figure 6), Japan plans to spend more than $2 billion on U.S. Tomahawk land-attack cruise missiles for emplacement on certain Maritime Self-Defense Force ships.129 As of 2023, Tokyo’s plans included the procurement of 400 Tomahawk land-attack cruise missiles.130
Taiwan
Taiwan has maintained a long-standing interest in the pursuit of ballistic and cruise missiles (see figure 7), with initial efforts at indigenously developing missile technology dating back to the 1970s. In the interest of preserving stability in the Taiwan Strait and global nonproliferation, the United States viewed a potential ballistic missile arsenal in Taiwan as destabilizing, particularly in the 1970s and 1980s, and discouraged its development.131 Taipei thereafter largely focused its efforts on cruise missiles—especially those that could be considered as defensive platforms against a Chinese amphibious invasion attempt, such as anti-ship cruise missiles—and surface-to-air missiles, which received the preponderance of Taiwanese research and development efforts as a result. The Hsiung Feng I/IA anti-ship cruise missiles and Tien-Kung 1 surface-to-air missile system were two early Taiwanese missile systems, each precipitating a series of anti-ship cruise missiles and surface-to-air missiles that remain relevant to this day. The first Hsiung Feng I anti-ship cruise missile test was carried out on July 27, 1975.132 Beginning in the late-1960s, Taiwan started flight-testing shorter-range Kung Feng-series rocket artillery systems.
Like its reservations about South Korea’s pursuit of long-range delivery systems in the 1970s, Washington was particularly concerned about Taiwanese interest in ballistic missile technologies due to concerns that Taipei might pursue nuclear weapons. Taiwan aborted its clandestine effort at building nuclear weapons in 1988 under U.S. pressure,133 and it further abandoned efforts to build a nearly 1,000-kilometer-range ballistic missile system under the Tien Ma program.134 Despite this, Taiwan has sustained a substantial base of domestic knowledge on missile development, focused on cruise missiles.
Emphasis on Offense in Taiwanese Missile Strategy
The primary driver of Taiwanese investments in missiles has been the long-perceived threat of an invasion of its territory from the People’s Republic of China. As China’s own ballistic and cruise missile capabilities expanded in the 1980s and 1990s, Taiwan largely saw a need to keep pace with its own capabilities—particularly those that would be able deliver tactical and strategic effects against fixed and mobile targets in Chinese territory. Despite U.S. encouragement during this time to invest in missile defenses, Taiwanese policymakers almost universally saw offensive missile capabilities as the most cost-effective means to deter Beijing.135 By the 1990s, Taiwan’s substantial investments in indigenous missile research and development efforts and growing expertise likely also buttressed Taipei’s belief that it could sustain and scale an indigenous missile force without necessarily relying on the United States. Following the U.S. normalization of diplomatic relations with China in 1979, Taiwan ceased to benefit from the formal, treaty-codified U.S. extended deterrence assurances that had been in place since 1954.136 In 1979, the U.S. Congress enacted the Taiwan Relations Act, which has since governed the unofficial relationship between the United States and Taiwan and included a commitment to “make available to Taiwan such defense articles and defense services in such quantity as may be necessary to enable Taiwan to maintain a sufficient self-defense capacity.”137 The Ronald Reagan administration extended six assurances to Taipei that included a commitment to continue arms sales to Taiwan indefinitely and without consultation with Beijing.138
Despite these continuing U.S. statements of support, policymakers in Taipei still saw a necessity to continue investing in missile capabilities. The locus of indigenous expertise in missile technologies and missile development in Taiwan largely rests with the National Chung-Shan Institute of Science and Technology (NCSIST). NCSIST undertakes defense research and development activities relating to a range of technologies with defense applications. Through the 1990s, while interest in ballistic missile defenses appeared to grow around the world following U.S. claims concerning the role of Patriot missile defense systems in the first Gulf War, Taipei remained skeptical of the cost effectiveness of missile defense. (U.S. claims concerning the performance of Patriot against Scuds in that war were later shown to have been significantly exaggerated.139) In 1995, then Taiwanese defense minister Chiang Chung-ling underscored another component of Taipei’s reasoning about the value of missile systems, publicly hinting before Taiwanese legislators that such capabilities could contribute to a campaign of preemption against Chinese missile launchers: “Undoubtedly, the best defense strategy is to attack . . . the best defense measure is to destroy the [Chinese] M-class missiles before they are launched.”140 At the time, this was an unusually transparent and authoritative statement from a Taiwanese official on the purpose of Taipei’s continuing investments in missile capabilities. Taiwan had maintained substantial opacity regarding its missile development efforts at NCSIST; this opacity persisted for decades and has only recently begun to give way to greater transparency. Less than a year after Chiang’s public remarks, in the course of what would come to be known as the Third Taiwan Strait Crisis, China’s Second Artillery Corps fired DF-15 ballistic missiles during live-fire exercises, spotlighting Beijing’s missile capabilities and reaffirming Taiwanese threat perceptions.141 In the aftermath of the crisis, Taiwan expanded its missile-related research and development activities, which included efforts to convert anti-ship cruise missiles into land-attack cruise missiles.142
In the twenty-five years since the Third Taiwan Strait Crisis, China’s ballistic and cruise missile arsenal and its conventional military capabilities more generally have grown substantially. Since the 2016 election in Taiwan, when Democratic Progressive Party candidate Tsai Ing-wen became president, cross-strait relations have declined precipitously. China views Tsai and her party as insufficiently committed to Beijing’s interpretation of the One China principle and as positively disposed toward formal independence for Taiwan. Moreover, intensifying geopolitical rivalry between the United States and China has largely shed Washington of its earlier encouragement of restraint concerning the pursuit of strike capabilities by Taipei. Under both the Trump and Biden administrations, the United States has continued to support robust defensive arms sales to Taiwan and has actively encouraged Taipei to pursue capabilities that could contribute to deterrence by denial of a Chinese amphibious invasion through the pursuit of anti-ship cruise missiles, among other weapon systems—but not dedicated land-attack systems. Even before these developments, by the end of the 2010s, analyses of the cross-strait military balance emphasized Taiwan’s limited ability to cope with the capabilities China could bring to bear in an invasion scenario.143
Ongoing Investments in Missiles
Due to Taipei’s general restraint in the pursuit of ballistic missile technologies, most of its deployed missiles and missiles under development are cruise missiles of varying speed and sophistication. The most prominent of Taiwan’s operational missiles is the Hsiung Feng IIE land-attack cruise missile, which features a 600-kilometer range, giving it the ability to hold at risk targets well within mainland China (primarily Fujian Province, but also parts of Zhejiang, Guangdong, and Jiangxi Provinces). The Hsiung Feng IIE is the primary deployed long-range surface-attack missile; another missile, known as Yun Feng (discussed later), is under development and will allow Taiwan to hold at risk targets deeper in mainland China. The bulk of Taiwan’s other indigenous operational missiles are anti-ship cruise missiles and air-to-surface cruise missiles. These include both the Hsiung Feng II and Hsiung Feng III anti-ship cruise missiles, each of which is a close-range missile (120–150 kilometers), and the air-launched Wan Chien cruise missile, with a slightly longer, 240-kilometer range. The Wan Chien’s range can be practically extended if its launch platform, the F-CK-1 C/D Ching-kuo fighter, is able to leave Taiwanese airspace in the direction of mainland China. (This airspace would be highly contested in times of conflict, and Taiwanese fighters would be vulnerable to ship- and shore-based air defenses.) Taiwan’s lone, known deployed ballistic missile capability is in the form of the solid-propellant, short-range Tien Chi missile, which is thought to be derived from a surface-to-air missile.144 Sources vary in range assessments of the Tien Chi, but it is probable that the missile could deliver a light, conventional high-explosive payload to around 300 kilometers,145 allowing for strikes on mainland Chinese targets near the coast from forward island bases.
Taiwan has traditionally been concerned about the survivability of its own missile force, particularly as China’s long-range precision strike capabilities have grown in the post–Cold War era. Taipei has generally been hesitant to publicize details about its missile capabilities. Until recently, images of prominent Taiwanese missile systems, such as the Hsiung Feng III, were not released by official sources. At one point, Taiwan explored the possibility of disguising Hsiung Feng IIE mobile launchers as commercial delivery vehicles—a decision that one Taiwanese military official would later describe to the press as “idiotic” and “embarrassing” following disclosures by open-source analysts.146 Taipei has also been reluctant to confirm the existence of certain missile programs. For instance, for years, rumors swirled about a Taiwanese program, known as Yun Feng, to develop a long-range surface-to-surface missile designed to hold at risk targets deep within China. The Taiwanese military confirmed the existence of such a program in October 2021 for the first time.147 The Yun Feng is not a ballistic missile system but a probable ramjet-equipped, supersonic land-attack cruise missile; it may be partially derived from the Hsiung Feng III. Taiwanese press reported that a series of Yun Feng launches took place in April 2020, but this was not officially confirmed.148 In June 2022, You Si-kun, the president of Taiwan’s Legislative Yuan, alluded to the ability of the Yun Feng missile to strike Beijing, implying that the missile could play the role of retaliating against China’s senior political leadership in the context of an invasion.149 You alluded to Russia’s invasion of Ukraine, juxtaposing Taiwan’s apparent ability to strike deep within China with Ukraine’s relatively more limited strike capabilities.150 Since 2021, Taiwan has substantially deepened its investments in missile systems, including through the passage of a supplementary defense budget in 2021.151 According to a senior Taiwanese official, Taiwan’s indigenous missile production is expected to surpass 1,000 missiles across all range classes in 2023.152
Beyond its indigenous capabilities, Taiwan continues to source a number of precision strike systems from the United States. Washington has continued to approve the sale of various missile systems to Taipei. In October 2020, the United States announced an intention to sell 135 270-kilometer AGM-84H Standoff Land Attack Missile Expanded Response (SLAM-ER);153 eleven High-Mobility Artillery Rocket Systems (HIMARS) M142 launchers,154 along with associated munitions; and 400 124-kilometer RGM-84L-4 Harpoon Block II Surface Launched dual-mode anti-ship and land-attack missiles.155 These were in addition to a package of Block I-92F shoulder-fired surface-to-air Stinger missiles and Block I-92F Stinger Fly-to-Buy missiles approved in July 2019. Additional U.S.-Taiwan cooperation may result in the joint production of U.S. weapons in Taiwan, according to officially uncorroborated press reports,156 although the United States is unlikely to authorize production capabilities that would meaningfully assist Taiwan’s ability to produce ballistic or cruise missiles. U.S. concern over the possible unintended transfer of intellectual property or leaks of classified information relating to certain missile systems could preclude the finalization of such an agreement. Nevertheless, U.S. interest in coproducing missiles in Taiwan in the 2020s underscores the substantial shifts in Washington’s prior encouragement of restraint in Taipei, largely as a function of growing geopolitical rifts with Beijing and concerns about a deliberate invasion of Taiwan. U.S. lawmakers are further considering the acceleration of arms sales to Taiwan, including the provision of anti-ship, anti-air, and anti-tank missile systems, through the foreign military financing program.157
Notes
1 For background on the history and bureaucratic drivers of China’s missile development, see David C. Logan, “Making Sense of China’s Missile Forces,” in Chairman Xi Remakes the PLA: Assessing Chinese Military Reforms, ed. Philip C. Saunders et al. (Washington, DC: National Defense University Press, 2019), 393–394.
2 Dual-capable missiles are systems intended for the delivery of both nuclear and conventional payloads, with both types of warheads available. Conventional missiles are inherently capable of delivering nuclear weapons if appropriate warheads are available and manufactured. For more on payloads and ambiguity, see Acton, “Is It a Nuke?”
3 No Chinese cruise missiles are currently known to be intended for use with nuclear warheads.
4 “Military and Security Developments Involving the People’s Republic of China,” Office of the U.S. Secretary of Defense, 2021, https://media.defense.gov/2021/Nov/03/2002885874/-1/-1/0/2021-CMPR-FINAL.PDF.
5 M. Taylor Fravel, “China’s ‘World-Class Military’ Ambitions: Origins and Implications,” Washington Quarterly 43, no. 1 (January 2, 2020): 85–99, https://doi.org/10.1080/0163660X.2020.1735850.
6 Xiu Ma, PLA Rocket Force Organization (Montgomery, AL: China Aerospace Studies Institute/Blue Path Labs, 2021), 4.
7 This is an organizational term that does not correspond to distinct individual facilities.
8 Bases 67, 68, and 69 are involved in training, support, logistics, testing, and nuclear warhead management.
9 PLARF base locations and compositions have been constructed from open sources by various analysts outside of China. See Jeffrey Lewis, David Joel La Boon, and Decker Eveleth, “China’s Growing Missile Arsenal and the Risk of a ‘Taiwan Missile Crisis’,” Nuclear Threat Initiative, November 18, 2020, https://www.nti.org/analysis/articles/chinas-growing-missile-arsenal-and-the-risk-of-a-taiwan-missile-crisis.
10 “Military and Security Developments Involving the People’s Republic of China,” Office of the U.S. Secretary of Defense, 2020, https://media.defense.gov/2020/Sep/01/2002488689/-1/-1/1/2020-DOD-CHINA-MILITARY-POWER-REPORT-FINAL.PDF.
11 “Military and Security Developments Involving the People’s Republic of China,” U.S. Department of Defense, 2022, 167, https://media.defense.gov/2022/Nov/29/2003122279/-1/-1/1/2022-MILITARY-AND-SECURITY-DEVELOPMENTS-INVOLVING-THE-PEOPLES-REPUBLIC-OF-CHINA.PDF.
12 Acton, “Is It a Nuke?,” 31–33.
13 Zuzanna Gwadera, “Intelligence Leak Reveals China’s Successful Test of a New Hypersonic Missile,” International Institute for Strategic Studies, May 18, 2023, https://www.iiss.org/en/online-analysis/online-analysis/2023/05/intelligence-leak-reveals-chinas-successful-test-of-a-new-hypersonic-missile/.
14 Ankit Panda, “Introducing the DF-17: China’s Newly Tested Ballistic Missile Armed With a Hypersonic Glide Vehicle,” December 28, 2017, 17, https://thediplomat.com/2017/12/introducing-the-df-17-chinas-newly-tested-ballistic-missile-armed-with-a-hypersonic-glide-vehicle. The DF-17 was described as a “strategic nuclear system” by a senior U.S. military official in congressional testimony in 2020. See Charles A. Richard, “Statement of Charles A. Richard, Commander, United States Strategic Command, Before the Senate Committee on Armed Services,” February 13, 2020, 4, https://www.armed-services.senate.gov/imo/media/doc/Richard_02-13-20.pdf.
15 Xuanzun Liu, “China’s Hypersonic Cruise Missile Sees Technological Breakthrough: Reports,” Global Times, June 8, 2020, https://www.globaltimes.cn/content/1190877.shtml.
16 For a survey of China’s cruise missile development efforts, see Dennis M. Gormley, Andrew S. Erickson, and Jingdong Yuan, “A Potent Vector: Assessing Chinese Cruise Missile Developments,” Joint Force Quarterly 75 (September 30, 2014), https://ndupress.ndu.edu/Media/News/News-Article-View/Article/577568/a-potent-vector-assessing-chinese-cruise-missile-developments/.
17 Andrew S. Erickson, Chinese Anti-Ship Ballistic Missile (ASBM) Development: Drivers, Trajectories, and Strategies (Brookings Institution Press and Jamestown Foundation, 2013), https://www.jstor.org/stable/10.7864/j.ctt1dgn67n.
18 “#HFX2020: Admiral Philip Davidson,” YouTube video, posted by “Halifax International Security Forum,” November 20, 2020, https://www.youtube.com/watch?v=7q5mvRJyGrw. The U.S. Department of Defense’s 2021 report on Chinese military capabilities further specified that the tests in 2020 were against “a moving target in the South China Sea.” See “Military and Security Developments Involving the People’s Republic of China,” Office of the U.S. Secretary of Defense, 2021, 61.
19 H. I. Sutton and Sam LaGrone, “China Builds Missile Targets Shaped Like U.S. Aircraft Carrier, Destroyers in Remote Desert,” USNI News, November 7, 2021, https://news.usni.org/2021/11/07/china-builds-missile-targets-shaped-like-u-s-aircraft-carrier-destroyers-in-remote-desert.
20 “2020 Science of Military Strategy,” China Aerospace Studies Institute, January 26, 2022, 138, 271, https://www.airuniversity.af.edu/CASI/Display/Article/2913216/in-their-own-words-2020-science-of-military-strategy.
21 “2020 Science of Military Strategy,” 385.
22 “2020 Science of Military Strategy,” 385.
23 “2020 Science of Military Strategy,” 389.
24 M. Taylor Fravel, Active Defense: China’s Military Strategy Since 1949 (Princeton, NJ: Princeton University Press, 2019), 166.
25 Fravel, Active Defense, 230–234.
26 “2020 Science of Military Strategy,” 385.
27 “Full Text: China’s Military Strategy,” Ministry of National Defense of the People’s Republic of China, May 26, 2015, http://www.china.org.cn/china/2015-05/26/content_35661433.htm.
28 M. Taylor Fravel, “China’s New Military Strategy: ‘Winning Informationized Local Wars,’” Jamestown Foundation, July 2, 2015, https://jamestown.org/program/chinas-new-military-strategy-winning-informationized-local-wars.
29 This text is formally classified, but it was leaked to sources outside China and has since been unofficially translated into English.
30 PLA Second Artillery Corps, The Science of Second Artillery Campaigns (Beijing: PLA Press, 2004), 318.
31 PLA Second Artillery Corps, The Science of Second Artillery Campaigns, 317.
32 PLA Second Artillery Corps, The Science of Second Artillery Campaigns, 317–335.
33 PLA Second Artillery Corps, The Science of Second Artillery Campaigns, 272; and Rosemary J. Foot, “Nuclear Coercion and the Ending of the Korean Conflict,” International Security 13, no. 3 (1988): 92–112, https://doi.org/10.2307/2538737.
34 “Statement by Peking on Nuclear Test,” New York Times, October 17, 1964, https://www.nytimes.com/1964/10/17/archives/statement-by-peking-on-nuclear-test.html.
35 Thomas Shugart, “First Strike: China’s Missile Threat to U.S. Bases in Asia,” June 28, 2017, https://www.cnas.org/publications/reports/first-strike-chinas-missile-threat-to-u-s-bases-to-asia; and Eric Heginbotham et al., “Chinese Attacks on U.S. Air Bases in Asia: An Assessment of Relative Capabilities, 1996–2017,” RAND Corporation, September 14, 2015, https://www.rand.org/pubs/research_briefs/RB9858z2.html
36 Caitlin Talmadge, “Would China Go Nuclear? Assessing the Risk of Chinese Nuclear Escalation in a Conventional War With the United States,” International Security 41, no. 4 (April 1, 2017): 50–92, https://doi.org/10.1162/ISEC_a_00274.
37 PLA Second Artillery Corps, The Science of Second Artillery Campaigns, 54.
38 Yimou Lee and Sarah Wu, “Furious China Fires Missiles Near Taiwan in Drills After Pelosi Visit,” Reuters, August 5, 2022, https://www.reuters.com/world/asia-pacific/suspected-drones-over-taiwan-cyber-attacks-after-pelosi-visit-2022-08-04.
39 Helen Davidson, “China Ends Military Drills After Simulating Strikes on Taiwan,” The Guardian, April 10, 2023, https://www.theguardian.com/world/2023/apr/10/china-simulates-strikes-on-taiwan-from-aircraft-carriers-as-drills-enter-third-day. The animation was shared on Twitter by the Global Times, among other Chinese outlets. See Global Times (@globaltimesnews), “WATCH: A computer generated animation by the PLA Eastern Theater Command shows its mock joint precision strikes on the island of Taiwan on Sunday,” Twitter post and video, April 9, 2023, 3:49 a.m., https://twitter.com/globaltimesnews/status/1644970821977526272.
40 Nicholas Seltzer, “Baekgom: The Development of South Korea’s First Ballistic Missile,” Nonproliferation Review 26, no. 3–4 (May 4, 2019): 289–327, https://doi.org/10.1080/10736700.2019.1659541.
41 Peter Crail, “South Korea Unveils New Missile,” Arms Control Today, May 2012, https://www.armscontrol.org/act/2012-05/south-korea-unveils-new-missile.
42 These concepts were temporarily rebranded during the Moon Jae-in administration amid diplomacy with North Korea. The Kill Chain was renamed Strategic Target Strike, Korea Air and Missile Defense became Korea Missile Defense, and KMPR became Overwhelming Response. The Yoon Seok-yeol administration has since reversed these changes to the original naming conventions.
43 Daehan Lee, “South Korea to Create New Command That Would Control Strategic Weapons,” Defense News, July 11, 2022, https://www.defensenews.com/global/asia-pacific/2022/07/11/south-korea-to-create-new-command-that-would-control-strategic-weapons.
44 Ian Bowers and Henrik Stålhane Hiim, “Conventional Counterforce Dilemmas: South Korea’s Deterrence Strategy and Stability on the Korean Peninsula,” International Security 45, no. 3 (January 1, 2021): 7–39, https://doi.org/10.1162/isec_a_00399; and Manseok Lee and Hyeongpil Ham, “South Korea’s Conventional Forces Buildup: The Search for Strategic Stability,” War on the Rocks, April 16, 2021, https://warontherocks.com/2021/04/south-koreas-conventional-forces-buildup-the-search-for-strategic-stability.
45 Daniel A. Pinkston, “The New South Korean Missile Guidelines and Future Prospects for Regional Stability,” International Crisis Group, October 25, 2012, https://www.crisisgroup.org/asia/north-east-asia/korean-peninsula/new-south-korean-missile-guidelines-and-future-prospects-regional-stability.
46 Ankit Panda, “Solid Ambitions: The U.S.–South Korea Missile Guidelines and Space Launchers,” Carnegie Endowment for International Peace, August 25, 2020, https://carnegieendowment.org/2020/08/25/solid-ambitions-u.s.-south-korea-missile-guidelines-and-space-launchers-pub-82557.
47 Josh Smith, “S.Korea Says It Successfully Test-Fired First Solid-Fuel Space Rocket,” Reuters, March 30, 2022, https://www.reuters.com/world/asia-pacific/skorea-says-it-successfully-test-fired-first-solid-fuel-space-rocket-2022-03-30.
48 Smith, “S.Korea Says It Successfully Test-Fired.”
49 Bowers and Hiim, “Conventional Counterforce Dilemmas.”
50 This view was expressed by multiple South Korean defense analysts interviewed by the author in Seoul in 2021 and 2022.
51 Lami Kim, “A Hawkish Dove? President Moon Jae-in and South Korea’s Military Buildup,” War on the Rocks, September 15, 2021, https://warontherocks.com/2021/09/a-hawkish-dove-president-moon-jae-in-and-south-koreas-military-buildup.
52 “Defense Budget,” Ministry of National Defense of the Republic of Korea, accessed November 2, 2022, https://www.mnd.go.kr/mbshome/mbs/mndEN/subview.jsp?id=mndEN_030900000000.
53 “Address by President Moon Jae-in on the 69th Armed Forces Day,” Korea.net, September 28, 2017, https://www.korea.net/Government/Briefing-Room/Presidential-Speeches/view?articleId=149818&pageIndex=1.
54 “Joint Communiqué: The 46th ROK-U.S. Security Consultative Meeting,” U.S. Department of Defense, October 24, 2014, https://dod.defense.gov/Portals/1/Documents/pubs/46th_SCM_Joint_Communique.pdf.
55 Sang-ho Song, “Moon Stresses Need for Defense Capabilities Befitting S. Korea’s Geopolitical Position,” Yonhap, December 26, 2021, https://en.yna.co.kr/view/AEN20211226000700325.
56 Jaroslaw Adamowski, “Poland to Buy Hundreds of SKorean Chunmoo Multiple-Rocket Launchers,” Defense News, October 14, 2022, https://www.defensenews.com/global/europe/2022/10/14/poland-to-buy-hundreds-of-s-korean-chunmoo-multiple-rocket-launchers.
57 Mark Cazalet et al., “South Korea Testing Several New Missiles Amid Tensions With Pyongyang,” Janes.com, September 15, 2021, https://www.janes.com/defence-news/news-detail/south-korea-testing-several-new-missiles-amid-tensions-with-pyongyang.
58 Soo-hyang Choi, “S. Korea Develops Supersonic Cruise Missile Amid Tensions With N. Korea,” Yonhap, September 15, 2021, https://en.yna.co.kr/view/AEN20210915010951325.
59 Daehan Lee, “South Korea Reveals Plans to Deter China via A2/AD,” Naval News, January 12, 2022, https://www.navalnews.com/naval-news/2022/01/south-korea-reveals-plans-to-deter-china-via-a2-ad.
60 Hyonhee Shin, “S.Korea Says It Successfully Tests Submarine-Launched Ballistic Missile,” Reuters, September 15, 2021, https://www.reuters.com/business/aerospace-defense/skorea-successfully-tests-submarine-launched-ballistic-missile-blue-house-2021-09-15.
61 Surveys from 2021 found that 71 percent of the South Korean public supported the development of an independent nuclear deterrent. See Toby Dalton, Karl Friedhoff, and Lami Kim, “Thinking Nuclear: South Korean Attitudes on Nuclear Weapons,” Chicago Council on Global Affairs, February 21, 2022), https://globalaffairs.org/research/public-opinion-survey/thinking-nuclear-south-korean-attitudes-nuclear-weapons; and 기자김상진, “여당 북핵대응특위 ‘핵무장 비밀 프로젝트 추진해야,’” 중앙일보, November 24, 2022, https://www.joongang.co.kr/article/25120044.
62 Ankit Panda, Kim Jong Un and the Bomb: Survival and Deterrence in North Korea (Oxford University Press, 2020), 138–140.
63 Ankit Panda, “North Korea’s New KN19 Coastal Defense Cruise Missile: More Than Meets the Eye,” The Diplomat, July 26, 2017, 19, https://thediplomat.com/2017/07/north-koreas-new-kn19-coastal-defense-cruise-missile-more-than-meets-the-eye; and Ankit Panda, “Introducing the KN21, North Korea’s New Take on Its Oldest Ballistic Missile,” The Diplomat, September 14, 2017, 21, https://thediplomat.com/2017/09/introducing-the-kn21-north-koreas-new-take-on-its-oldest-ballistic-missile.
64 “On Report Made by Supreme Leader Kim Jong Un at Eighth Party Congress of WPK,” National Committee on North Korea, January 25, 2021, https://www.ncnk.org/resources/publications/kju_8th_party_congress_speech_summary.pdf/file_view.
65 Ankit Panda, “A Call to Arms: Kim Jong Un and the Tactical Bomb,” Washington Quarterly 44, no. 3 (July 3, 2021): 8–9, https://doi.org/10.1080/0163660X.2021.1969089.
66 Josh Smith and Hyonhee Shin, “Analysis: North Korea Signals Expansive Mission for Its Nuclear Weapons,” Reuters, April 27, 2022, https://www.reuters.com/world/asia-pacific/north-korea-signals-expansive-mission-its-nuclear-weapons-2022-04-27.
67 “DPRK’s Law on Policy of Nuclear Forces Promulgated,” KCNA Watch, September 9, 2022, https://kcnawatch.org/newstream/1662721725-307939464/dprk%E2%80%99s-law-on-policy-of-nuclear-forces-promulgated.
68 Panda, “A Call to Arms.”
69 Vipin Narang and Ankit Panda, “Command and Control in North Korea: What a Nuclear Launch Might Look Like,” War on the Rocks, September 15, 2017, https://warontherocks.com/2017/09/command-and-control-in-north-korea-what-a-nuclear-launch-might-look-like.
70 Panda, Kim Jong Un and the Bomb, 245.
71 Jeongmin Kim, “North Korea’s Lake-Launched Missile Complicates Seoul’s Defense Plans: Experts,” NK News, October 11, 2022, https://www.nknews.org/2022/10/north-koreas-lake-launched-missile-complicates-seouls-defense-plans-experts.
72 For instance, many of North Korea’s endoatmospheric aeroballistic missiles have exhibited glide trajectories within the 40-to-60-kilometer range. The Patriot Advanced Capability-3 interceptor may lack an ability to engage targets effectively over 40 kilometers, based on open sources, and the Terminal High Altitude Area Defense system interceptor has an engagement “floor” of 50 kilometers. See Brian Kim, “South Korea to Buy More Patriot Missiles, Upgrade Launchers,” Defense News, June 6, 2022, https://www.defensenews.com/global/asia-pacific/2022/06/06/south-korea-to-buy-more-patriot-missiles-upgrade-launchers; and Michael Elleman and Michael J Zagurek, “THAAD: What It Can and Can’t Do,” 38 North, March 10, 2016, 13, https://www.38north.org/wp-content/uploads/pdf/2016-03-10_THAAD-What-It-Can-and-Cant-Do.pdf. The author is grateful to the late Michael Elleman for raising this point during a private exchange in 2019.
73 Australian Department of Defence, “2016 Defence White Paper,” June 2020, https://www.defence.gov.au/about/strategic-planning/2016-defence-white-paper.
74 Australian Department of Defence, “2020 Defence Strategic Update,” July 1, 2020, https://www.defence.gov.au/sites/default/files/2020-11/2020_Defence_Strategic_Update.pdf.
75 Australian Department of Defence, “Defence Strategic Review 2023,” 2023, https://www.defence.gov.au/about/reviews-inquiries/defence-strategic-review.
76 SIPRI Military Expenditure Database, Stockholm International Peace Research Institute.
77 “The Australia, New Zealand and United States Security Treaty (ANZUS Treaty), 1951,” Office of the Historian, U.S. Department of State, accessed October 21, 2022, https://history.state.gov/milestones/1945-1952/anzus. Since 1986, New Zealand and the United States have no longer maintained the formal ANZUS collective defense arrangement. For background, see Daniel Mulhall, “New Zealand and the Demise of ANZUS: Alliance Politics and Small-Power Idealism,” Irish Studies in International Affairs 2, no. 3 (1987): 61–77, http://www.jstor.org/stable/30002014.
78 “The Force Posture Agreement between the Government of Australia and the Government of the United States of America,” Australian Department of Foreign Affairs and Trade, August 12, 2014, https://www.info.dfat.gov.au/Info/Treaties/Treaties.nsf/AllDocIDs/6441A500816C2902CA257D38001DB33D.
79 “Joint Leaders Statement on AUKUS,” White House, September 15, 2021, https://www.whitehouse.gov/briefing-room/statements-releases/2021/09/15/joint-leaders-statement-on-aukus.
80 Malcolm Davis, “AUKUS: Looking Beyond the Submarines,” The Strategist, November 4, 2021, https://www.aspistrategist.org.au/aukus-looking-beyond-the-submarines; and “AUKUS Leaders’ Level Statement,” White House, April 5, 2022, https://www.whitehouse.gov/briefing-room/statements-releases/2022/04/05/aukus-leaders-level-statement.
81 Peter Dutton, “$3.5 Billion to Accelerate Missile Strike Capabilities for the ADF,” Australian Department of Defence, April 5, 2022, https://www.minister.defence.gov.au/media-releases/2022-04-05/35-billion-accelerate-missile-strike-capabilities-adf.
82 Dutton, “$3.5 Billion to Accelerate Missile Strike Capabilities for the ADF.”
83 Scott Morrison and Peter Dutton, “Joint Media Statement: Australia to Pursue Nuclear-Powered Submarines Through New Trilateral Enhanced Security Partnership | Defence Ministers,” Australian Department of Defence, September 16, 2021, https://www.minister.defence.gov.au/statements/2021-09-16/joint-media-statement-australia-pursue-nuclear-powered-submarines-through-new-trilateral-enhanced-security-partnership; and Mallory Shelbourne, “Congress Notified of Potential $895M Tomahawk Sale to Australia,” USNI News, March 16, 2023, https://news.usni.org/2023/03/16/congress-notified-of-potential-895m-tomahawk-sale-to-australia.
84 Morrison and Dutton, “Joint Media Statement: Australia to Pursue Nuclear-Powered Submarines.”
85 Australian Department of Defence, “2020 Defence Strategic Update,” 40.
86 “U.S. Air Force Airmen, B-52H Bombers Arrive in Australia to Train With Australian Counterparts,” U.S. Indo-Pacific Command, March 30, 2018, https://www.pacom.mil/Media/News/News-Article-View/Article/1481370/us-air-force-airmen-b-52h-bombers-arrive-in-australia-to-train-with-australian.
87 “HIFiRE Program,” Defence Science and Technology Group, July 12, 2013, https://www.dst.defence.gov.au/partnership/hifire-program.
88 “Department of Defense Announces New Allied Prototyping Initiative Effort With Australia to Continue Partnership in Developing Air Breathing Hypersonic Vehicles,” U.S. Department of Defense, November 30, 2020, https://www.defense.gov/News/Releases/Release/Article/2429061/department-of-defense-announces-new-allied-prototyping-initiative-effort-with-a.
89 Kathy Barnstorff, “HIFiRE Scramjet Research Flight Will Advance Hypersonic Technology,” U.S. National Aeronautics and Space Administration, May 10, 2012, http://www.nasa.gov/topics/aeronautics/features/hifire.html.
90 Greg Waldron, “US, Australia Conclude Secretive Hypersonic Flight Series,” Flight Global, July 12, 2017, https://www.flightglobal.com/us-australia-conclude-secretive-hypersonic-flight-series/124771.article.
91 “AUKUS Leaders’ Level Statement,” White House.
92 GlobalData, “Australian Interest in Lockheed Martin’s PrSM Cements Future HIMARS Purchase,” Army Technology, August 24, 2021, https://www.army-technology.com/comment/australia-lockheed-martin-prsm.
93 Australian Department of Defence, “2020 Defence Strategic Update,” 40.
94 “3 December 2021 - GWEO Briefing by Major General Andrew Bottrell,” 19:00–22:00 YouTube video, posted by “DTCDefenseIndustry,” December 9, 2021, https://www.youtube.com/watch?v=x3M_VUCzNh4.
95 Author’s private correspondence with an Australian Defence Department official.
96 Adam P. Liff, “Policy by Other Means: Collective Self-Defense and the Politics of Japan’s Postwar Constitutional Reinterpretations,” Asia Policy, no. 24 (2017): 139–172, https://www.jstor.org/stable/26403212.
97 Ankit Panda, “US, Japan Agree to New Defense Guidelines,” The Diplomat, April 28, 2015, https://thediplomat.com/2015/04/us-japan-agree-to-new-defense-guidelines.
98 Michael Green, “The Challenges of Managing U.S.-Japan Security Relations After the Cold War,” in Curtis, ed., New Perspectives on U.S.-Japan Relations.
99 Louise Watt, “Japan Missile Plan on Ishigaki Island Helps Boost Taiwan Defense,” Nikkei Asia, August 20, 2021, https://asia.nikkei.com/Politics/International-relations/Japan-missile-plan-on-Ishigaki-island-helps-boost-Taiwan-defense.
100 “Marine Littoral Regiment (MLR),” United States Marine Corps Flagship, January 11, 2023, https://www.marines.mil/News/News-Display/Article/2708146/marine-littoral-regiment-mlr.
101 The NSM is a sub-200-kilometer-range system. For background, see Peter Ong, “Latest Details on the USMC’s NMESIS and Long Range USV,” Naval News, June 22, 2022, https://www.navalnews.com/naval-news/2022/06/latest-details-on-the-usmcs-nmesis-and-long-range-usv.
102 Lee Ferran and Ashley Roque, “Japan Signs Off on Marines Plan for New Littoral ‘Stand-In’ Group in Okinawa,” Breaking Defense, January 12, 2023, https://breakingdefense.sites.breakingmedia.com/2023/01/japan-signs-off-on-marines-plan-for-new-littoral-stand-in-group-in-okinawa.
103 Mari Yamaguchi, “Japan to Buy Aegis Ashore Missile Defense Systems,” Defense News, December 19, 2017, https://www.defensenews.com/land/2017/12/19/japan-to-buy-aegis-ashore-missile-defense-systems.
104 “Japan Aegis Ashore Missile Defense System Deployment Scrapped: Kono,” Kyodo News, June 25, 2020, https://english.kyodonews.net/news/2020/06/5cd95541475a-breaking-news-japan-scraps-plan-to-deploy-aegis-ashore-missile-defense-system-kono.html.
105 Author’s interviews with Japanese defense officials in Tokyo in November 2019.
106 Mari Yamaguchi, “Japan Ruling Party Urges Strike Ability Amid N. Korea Threat,” Associated Press, March 30, 2017, https://apnews.com/article/c5369a9db8d448ffb5e7c56e0d9c3630.
107 Associated Press, “Japan’s Defence Chief Seeks Local Support to Deploy a Missile Shield,” South China Morning Post, June 23, 2018, https://www.scmp.com/news/asia/east-asia/article/2152113/japans-defence-chief-seeks-local-support-deploy-land-based.
108 Reuters Staff, “Pacifist Japan Ruling Party Proposes Strike Capability to Halt Missile Attacks,” Reuters, July 31, 2020, https://www.reuters.com/article/us-japan-defence-idUSKCN24W09C.
109 Corey Wallace, “Japan and Foreign Territory Strike: Debate, Deterrence, and Defense Strength,” Journal Of Global Strategic Studies 1, no. 2 (December 29, 2021): 37, https://doi.org/10.36859/jgss.v1i2.846.
110 James L. Schoff and David Song, “Five Things to Know About Japan’s Possible Acquisition of Strike Capability,” Carnegie Endowment for International Peace, August 14, 2017, https://carnegieendowment.org/2017/08/14/five-things-to-know-about-japan-s-possible-acquisition-of-strike-capability-pub-72710.
111 Mina Pollmann, “Japan’s Ruling Coalition Debates Future Defense Policies,” The Diplomat, October 24, 2022, https://thediplomat.com/2022/10/japans-ruling-coalition-debates-future-defense-policies.
112 “Japan’s Counterstrike Capability Proposal to Ban Preemptive Attacks,” Kyodo News, November 13, 2022, https://english.kyodonews.net/news/2022/11/6b7dbca186b7-japans-counterstrike-capability-proposal-to-ban-preemptive-attacks.html.
113 Ankit Panda, “The US and Japan After the INF Treaty,” The Diplomat, December 1, 2019, https://thediplomat.com/2019/11/the-us-and-japan-after-the-inf-treaty.
114 Author’s conversations with Japanese defense experts and officials in November 2019.
115 Corey Wallace, “The Future of Japan’s Defense Is More Complicated Than It Looks,” Tokyo Review, September 14, 2020, https://www.tokyoreview.net/2020/09/the-future-of-japans-defense-is-more-complicated-than-it-looks. Privately, Japanese experts and officials have expressed similar views during interviews and conversations with the author.
116 “Japan Starts to Extend Range of Its Missiles to Over 1,000 Km,” Nikkei Asia, December 1, 2021, https://asia.nikkei.com/Politics/Japan-starts-to-extend-range-of-its-missiles-to-over-1-000-km.
117 Alastair Gale and Chieko Tsuneoka, “Japan to Spend Billions on U.S. Tomahawk Missiles in Military Buildup,” Wall Street Journal, December 23, 2022, https://www.wsj.com/articles/japan-to-spend-billions-on-u-s-tomahawk-missiles-in-military-buildup-11671784716.
118 “Japan Eyes Developing Standoff Missiles for Vessels, Fighter Jets,” Mainichi Daily News, June 5, 2021, https://mainichi.jp/english/articles/20210605/p2a/00m/0na/008000c.
119 “Japan to Develop 3,000-Km Long-Range Missiles, Deploy in 2030s, Kyodo Reports,” Reuters, December 31, 2022, https://www.reuters.com/business/aerospace-defense/japan-develop-3000-km-long-range-missiles-deploy-2030s-kyodo-2022-12-31.
120 Sam LaGrone, “Japanese MoD Releases New Details on Ballistic Missile Defense Ships,” USNI News, December 28, 2022, https://news.usni.org/2022/12/27/japanese-mod-releases-details-on-ballistic-missile-defense-ships.
121 “長射程ミサイル、潜水艦発射型を検討 反撃手段で防衛省,” 日本経済新聞, November 28, 2022, https://www.nikkei.com/article/DGXZQOUA24B6E0U2A121C2000000.
122 “Japan to Earmark 5 Tril. Yen for Long-Range Missiles Over 5 Years,” Kyodo News, December 7, 2022, https://english.kyodonews.net/news/2022/12/83976c4f0bc8-japan-to-earmark-5-tril-yen-for-long-range-missiles-over-5-years.html.
123 Based on the author’s conversations with certain Japanese security analysts.
124 “Medium Term Defense Program (FY 2019–FY 2023),” Japan Ministry of Defense, 2018, https://warp.da.ndl.go.jp/info:ndljp/pid/11591426/www.mod.go.jp/j/approach/agenda/guideline/2019/pdf/chuki_seibi31-35_e.pdf.
125 Alastair Gale, “Rising Threat From China Pushes U.S. and Japan to Deepen Military Cooperation,” Wall Street Journal, January 2, 2022, https://www.wsj.com/articles/rising-threat-from-china-pushes-u-s-and-japan-to-deepen-military-cooperation-11641138867.
126 Ryo Nakamura, “US Considers Midrange Missile Deployment in Asia to Counter China,” Nikkei Asia, August 15, 2020, https://asia.nikkei.com/Editor-s-Picks/Interview/US-considers-midrange-missile-deployment-in-Asia-to-counter-China.
127 “Press Briefing With Ambassador Marshall Billingslea, U.S. Special Presidential Envoy for Arms Control and Lt. Gen. Thomas Bussiere, Deputy Commander of the U.S. Strategic Command,” U.S. Department of State, August 18, 2020, https://2017-2021.state.gov/press-briefing-with-ambassador-marshall-billingslea-u-s-special-presidential-envoy-for-arms-control-and-lt-gen-thomas-bussiere-deputy-commander-of-the-u-s-strategic-command.
128 The U.S. Marine Corps operates HIMARS launchers equipped with short-range missiles in Japan, but no longer-range U.S. missile systems are deployed on Japanese soil.
129 Gale and Tsuneoka, “Japan to Spend Billions on U.S. Tomahawk Missiles in Military Buildup.”
130 Mari Yamaguchi, “Japan Signs $2.8 Billion Deals for Long-Range Missile Development,” Defense News, April 11, 2023, https://www.defensenews.com/global/asia-pacific/2023/04/11/japan-signs-28-billion-deals-for-long-range-missile-development.
131 Dennis M. Gormley, Missile Contagion: Cruise Missile Proliferation and the Threat to International Security, reprint edition (Annapolis, MD: Naval Institute Press, 2010), 43–44.
132 “History,” NCSIST, accessed November 13, 2022, https://www.ncsist.org.tw/eng/csistdup/aboutus/History.aspx#Map5.
133 David Albright and Andrea Stricker, Taiwan’s Former Nuclear Weapons Program: Nuclear Weapons On-Demand (Washington, DC: CreateSpace Independent Publishing Platform, 2018).
134 Gormley, Missile Contagion, 43. The exact date of the Tien Ma program’s cancellation is not known. News reports through the 1990s and early 2000s refer to the Tien Ma program, but most authoritative accounts describe it having been terminated in the 1980s.
135 Gormley, Missile Contagion, 43.
136 Hungdah Chiu, “Certain Legal Aspects of Recognizing the People’s Republic of China,” Case Western Reserve Journal of International Law 11, no.2 (1979): 33, https://scholarlycommons.law.case.edu/jil/vol11/iss2/7.
137 Clement J. Zablocki, “H.R.2479 - 96th Congress (1979-1980): Taiwan Relations Act,” legislation, April 10, 1979, 1979/1980, https://www.congress.gov/bill/96th-congress/house-bill/2479?s=1&r=7.
138 “Declassified Cables: Taiwan Arms Sales & Six Assurances (1982),” American Institute in Taiwan, March 30, 2022, https://www.ait.org.tw/declassified-cables-taiwan-arms-sales-six-assurances-1982.
139 Theodore A. Postol, “Lessons of the Gulf War Experience With Patriot,” International Security 16, no. 3 (1991): 119–71, https://doi.org/10.2307/2539090; Steve Fetter, George N. Lewis, and Lisbeth Gronlund, “Casualties and Damage From Scud Attacks in the 1991 Gulf War,” working paper, Defense and Arms Control Studies Program, Massachusetts Institute of Technology, March 1993, http://drum.lib.umd.edu/handle/1903/4334; and Eliot Marshall, “Patriot’s Scud Busting Record Is Challenged; MIT Weapons Analyst Theodore Postol Sees an Ominous Lesson: Cheap Decoys May Befuddle Costly Defenses,” Science 252, no. 5006 (May 3, 1991): 640–642, https://www.doi.org/10.1126/science.252.5006.640.
140 Dinshaw Mistry, Containing Missile Proliferation: Strategic Technology, Security Regimes, and International Cooperation in Arms Control (University of Washington Press, 2011), 99.
141 Chen Qimao, “The Taiwan Strait Crisis: Its Crux and Solutions,” Asian Survey 36, no. 11 (1996): 1,055–1,066, https://doi.org/10.2307/2645635.
142 Gormley, Missile Contagion, 44.
143 William S. Murray, “Revisiting Taiwan’s Defense Strategy,” Naval War College Review 61, no. 3 (2008): 3–4, https://digital-commons.usnwc.edu/nwc-review/vol61/iss3/3.
144 Wendell Minnick, “A Better Indigenous Missile Defense,” Taipei Times, July 13, 2001, https://www.taipeitimes.com/News/editorials/archives/2001/07/13/0000093969.
145 “Taiwan Switches From Tien Kung I to Tien Kung II,” Janes.com, July 5, 2006.
146 Wendell Minnick, “Taiwan’s Red Bird Express Service, Rain or Shine,” Intercepts (blog), Defense News, February 27, 2013, http://intercepts.defensenews.com/2013/02/taiwans-red-bird-express-service-rain-or-shine.
147 “Taiwan Military Confirms ‘Yun Feng’ Missile’s Existence,” Focus Taiwan, October 6, 2021, https://focustaiwan.tw/politics/202110060012.
148 Dorian Archus, “Taiwan Test-Fires Land-Attack Cruise Missile ‘Yun Feng,’” Naval Post, April 28, 2020, https://navalpost.com/taiwan-test-fires-land-attack-cruise-missile-yun-feng.
149 Emma Helfrich, “Taiwan Official Warns Supersonic Cruise Missile Can Strike Beijing,” The Drive, June 14, 2022, https://www.thedrive.com/the-war-zone/taiwan-official-warns-supersonic-cruise-missile-can-strike-beijing.
150 自由時報電子報, “游錫堃:雲峰飛彈可打到北京 中國侵台前須三思,” 自由時報電子報, June 12, 2022, https://news.ltn.com.tw/news/politics/breakingnews/3957585.
151 Matthew Strong, “Taiwan’s Legislative Yuan Passes NT$240-Billion Extra Budget for Missiles, Ships,” Taiwan News, November 23, 2021, https://www.taiwannews.com.tw/en/news/4353985.
152 Kelvin Chen, “Taiwan’s 2023 Missile Production Expected to Exceed 1,000,” Taiwan News, February 7, 2023, https://www.taiwannews.com.tw/en/news/4802562.
153 “Taipei Economic and Cultural Representative Office in the United States (TECRO) – AGM-84H Standoff Land Attack Missile-Expanded Response (SLAM-ER) Missiles,” Defense Security Cooperation Agency, October 21, 2020, https://www.dsca.mil/press-media/major-arms-sales/taipei-economic-and-cultural-representative-office-united-states-16.
154 “Taipei Economic and Cultural Representative Office in the United States (TECRO) – HIMARS, Support, and Equipment,” Defense Security Cooperation Agency, October 21, 2020, https://www.dsca.mil/press-media/major-arms-sales/taipei-economic-and-cultural-representative-office-united-states-15.
155 “Taipei Economic and Cultural Representative Office in the United States (TECRO) – RGM-84L-4 Harpoon Surface Launched Block II Missiles,” Defense Security Cooperation Agency, October 26, 2020, https://www.dsca.mil/press-media/major-arms-sales/taipei-economic-and-cultural-representative-office-united-states-17.
156 Ryo Nakamura, “U.S. in Talks With Taiwan to Coproduce American Weapons: Sources,” Nikkei Asia, October 19, 2022, https://asia.nikkei.com/Politics/International-relations/Taiwan-tensions/U.S.-in-talks-with-Taiwan-to-coproduce-American-weapons-sources.
157 Ellen Nakashima, “Congress Seeks to Arm Taiwan Quickly as China Threat Grows,” Washington Post, November 14, 2022, https://www.washingtonpost.com/national-security/2022/11/13/taiwan-china-invasion-military-aid.
The End of the INF Treaty and New U.S. Missiles
On August 18, 2019, U.S. Department of Defense officials gathered at the live munitions testing range San Nicolas Island off the coast of California to observe a missile test. At approximately 2:30 p.m., a cruise missile was ejected from an ordinary-looking rectangular canister. The missile flew out into the open ocean. A subsequent press release from the Department of Defense did not specify the total range covered but simply noted that the missile had “exited its ground mobile launcher and accurately impacted its target after more than 500 kilometers.”1 Normally, such a test would pass with little of note, but this was not an ordinary missile test; it marked the first time in at least thirty-two years that the United States had launched a non-intercontinental missile from a ground-based launcher to a range of more than 500 kilometers. The test was a direct result of Washington’s decision, which had taken effect about two weeks prior, to leave the 1987 INF Treaty, giving it newfound freedom of maneuver with regard to missile capabilities.2 With the launch, the United States made clear that the treaty’s erstwhile constraints no longer had bearing.
Although Washington maintained stocks of air- and sea-launched missiles that were outside of the INF Treaty’s scope through its life span, the arrival of new U.S. ground-launched, long-range precision strike systems to Asia will have implications for the country’s military strategy, warfighting plans, and escalation management. New U.S. deployments may have significant implications for the military balance in the Indo-Pacific—provided that Washington can find suitable territory for basing new missiles. As of 2023, no regional allies have acquiesced to basing new U.S. missiles or entered formal consultations.3 For U.S. adversaries such as China and North Korea, the end of the INF Treaty removes an important structural constraint on U.S. military power and a source of predictability. The prospect of new U.S. deployments against the backdrop of rapidly expanding allied and adversarial missile arsenals, as described in the previous chapter, deserves particular attention given the implications for regional stability. The central hinge point for regional stability and U.S. military planning, however, will continue to be the possibility of missile basing on allied territory.
The Rise and Fall of the INF Treaty
Negotiated between the United States and the Soviet Union in the final years of the Cold War, the INF Treaty was a notable first in the history of arms control because it eliminated an entire category of delivery systems. The two states permanently abjured all ground-launched ballistic and cruise missiles with ranges between 500 kilometers and 5,500 kilometers, irrespective of whether their payloads were nuclear or conventional. The treaty was originally envisaged as a means to manage concerns over missile-specific escalation risks in Europe, west of the Ural Mountains. However, allied exhortations, including by Japanese prime minister Nakasone Yasuhiro, motivated the United States to eventually seek a global scope for the treaty’s proscriptions.4 Over the course of the treaty’s implementation through 1991, 2,692 ground-launched U.S. and Soviet missiles were destroyed.5 Following the collapse of the Soviet Union, the treaty’s obligations were inherited by the Soviet successor states whose territories previously hosted proscribed missiles, including Belarus, Kazakhstan, Russia, Turkmenistan, Ukraine, and Uzbekistan.6 By the early 1990s, U.S.-aligned states in East Asia, as well as China, generally viewed the INF Treaty in positive terms.7
The INF Treaty was, above all, concerned with the basing mode of regional ballistic and cruise missiles—specifically, the U.S. Pershing II and BGM-109G Gryphon GLCM and the Soviet SS-4, SS-5, and SS-20. The immutable geography of continental Europe meant that NATO and Warsaw Pact forces were not only contiguous but that such missiles could be credibly and widely deployed on ground-based launchers with a plausible case for their military utility. NATO’s dual-track decision in 1979 resolved both to seek to negotiate limits and to address the apparent gap that had emerged between its own deployments and the Soviet Union’s deployments of the modern, mobile, MIRVed SS-20 in the second half of the 1970s. The dual-track approach incorporated “two parallel and complementary approaches,” namely deploying U.S. missiles to Europe while seeking to use these same missiles as leverage in arms control diplomacy.8 NATO concerns over the challenge that Soviet intermediate-range missiles posed to the credibility of the U.S. extended deterrent, as well as Soviet concerns over the short flight times and precision of systems such as the Pershing II, over time allowed for the treaty to manifest (with no shortage of negotiating difficulties between the two sides throughout the 1980s).
In 2014, the United States, under the Obama administration, first alleged that Russia was “in violation of its obligations under the INF Treaty not to possess, produce, or flight-test a GLCM with a range capability of 500 km to 5,500 km, or to possess or produce launchers of such missiles.”9 On March 8, 2017, less than two months after Trump’s inauguration, General Paul J. Selva, the vice chairman of the U.S. Joint Chiefs of Staff, testified before U.S. lawmakers that Russia had “deployed” a missile that he assessed “violates the spirit and intent” of the INF Treaty.10 Later that year, an official revealed that the missile in question was the 9M729 (NATO designation: SSC-8 Screwdriver).11 Russian noncompliance with the treaty took on particular urgency for the Trump administration, which partly used the noncompliance to justify its decision to pursue a nuclear-armed sea-launched cruise missile in its 2018 Nuclear Posture Review.12 The dispute festered between Moscow and Washington for more than two years, culminating in an announcement by Trump on October 20, 2018, that he would “terminate” the treaty. This announcement was made following a political rally in the U.S. state of Nevada,13 but the United States did not formally invoke the treaty’s six-month withdrawal period until February 2, 2019.14
The U.S. withdrawal from the treaty sparked concern in Europe, where the decision was not fully expected. It also raised questions about what role U.S. concern about Chinese capabilities might have played. During the initial announcement of withdrawal, Trump cited apparent concerns about China’s missiles, highlighting the country’s nonparticipation in the treaty.15 Long before that, senior U.S. military officials had expressed concerns about Beijing’s growing ground-launched missile capabilities. In 2017, the former commander of U.S. Pacific Command, Admiral Harry B. Harris, testified before U.S. lawmakers that the United States had “no comparable capability” to the PLARF’s “diverse missile force” in part “due to our adherence to” the INF Treaty.16 Harris added that “95% of the PLARF’s missiles would violate the INF [Treaty] if China was a signatory.”17 Harris’s public testimony reflected the U.S. Pacific Command’s growing sense at that time that the INF Treaty was not fit for purpose in the emerging geopolitical environment in East Asia, where military competition with China may require the United States to seek capabilities that had not previously been deployed to the region. In part, growing interest in archipelagic defense strategies that would seek to deny the PLA freedom of maneuver in and around the first island chain began to grow more prominent in U.S. strategic discourse during this period, increasing interest in new ground-launched missile capabilities.18
Unsurprisingly, China reacted sharply and negatively to the U.S. decision to “terminate” the INF Treaty. Shortly after a U.S. prototype intermediate-range ballistic missile test in December 2019, a Chinese Ministry of Foreign Affairs spokesperson said the United States was trying to “free itself to develop advanced missiles and seek unilateral military advantage.”19 Generally, the end of the treaty represented a sharply negative development in the eyes of Chinese officials and strategists. While China was able to advance its own ground-based missile capabilities without constraint over the treaty’s thirty-two years, the treaty’s end meant the evaporation of the assurance that Beijing would have to concern itself solely with air- and sea-launched U.S. long-range conventional strike platforms in the Indo-Pacific and the possible conclusion of China’s monopoly on ground-based land-attack intermediate-range missiles in East Asia. Indeed, the potential arrival of ground-launched U.S. missiles in Asia will add complexity to the PLA’s military planning and targeting. Official Chinese statements in the aftermath of the treaty’s demise warned U.S. allies against hosting possible new U.S. missiles capabilities; a Chinese Ministry of Defense spokesperson said that “if the U.S. forces its way through, it would severely sabotage regional countries’ security interests and harm peace and stability.”20
The United States’ Post–INF Treaty Plans
The end of the INF Treaty immediately led the United States to initiate various research and development programs for new missile systems. It quickly moved in 2019, after its withdrawal from the treaty took effect, to carry out two significant missile demonstrations. The first, mentioned at the outset of this chapter, involved a GLCM fired from a land-based variant of the shipborne Mark 41 Vertical Launch System used for Tomahawk cruise and other missiles. A second test, in December 2019, showcased a ground-launched intermediate-range ballistic missile, which “terminated in the open ocean after more than 500 kilometers of flight,” according to the U.S. Department of Defense. Both tests were rapidly conceived and carried out by the department’s Strategic Capabilities Office. The office has remained involved with U.S. post–INF Treaty missile development efforts, including with the U.S. Marine Corps’ efforts to field a “ground-based, long-range, land attack cruise missile capability for employment by its rocket artillery units.”21
Since these demonstrations, practical U.S. plans for the deployment of new conventionally armed, ground-launched land-attack missiles in the post–INF Treaty Indo-Pacific remain limited. By the end of 2019, as many as six new missile programs, with varying levels of funding, took shape to potentially lead to deployable ground-launched missiles that previously would have been prohibited by the INF Treaty. These efforts were largely led by the U.S. Army. Starting with the 2018 National Defense Strategy and its Multi-Domain Operations concept,22 the army began to emphasize long-range precision fires as an essential capability for future warfighting against near-peer adversaries. However, some of these programs have seen their funding zeroed out or have otherwise been mothballed in favor of concentrating resources into other programs. For instance, the army terminated research and development efforts for a 1,500-kilometer-range Strategic Long-Range Cannon in 2022, citing redundancy with other planned capabilities.23 A month after the Trump administration first stated its intention to withdraw from the INF Treaty, the army’s fiscal year 2020 budget request in February 2019 sought funding for a new “Mobile Medium Range Missile.” The notional purpose of this missile was to seek a “lower cost strategic capability that can attack specific threat vulnerabilities in order to penetrate, disintegrate, and exploit in the strategic and deep maneuver areas.”24 Funding for this system was zeroed out in the army’s fiscal year 2021 budget request, citing a “realignment of funds to higher priority programs.”25 Finally, in late 2019, reports suggested that the United States would seek to develop a ground-launched, intermediate-range ballistic missile with a 3,000-to-4,000-kilometer range,26 but no such system currently is under development.
More recently, U.S. Army plans have broadly coalesced around three missile systems, each with differing qualitative and range-coverage characteristics. These new ground-launched capabilities are a direct result of the expiration of INF Treaty constraints, against the background of the increased and substantial utility of accurate ballistic and cruise missiles in conventional warfare and the resort to such systems by U.S. adversaries. The first of these, the PrSM, was under development as a treaty-compliant replacement for the 300-kilometer ATACMS. The PrSM has seen incremental range extensions from the prior, declared treaty-compliant range of 499 kilometers to around 1,000 kilometers.27 Among U.S. post–INF Treaty capabilities, the PrSM was the furthest along in development as of late 2022 and may be fielded by the army as soon as 2023. Existing M142 HIMARS integrated road-mobile launchers that can carry a single ATACMS missile will be able to carry two PrSM missiles. As of the end of 2022, the first generation of the PrSM had entered the engineering and manufacturing development phase; a second generation PrSM missile will reach early operational capability by the 2027 fiscal year.28 In August 2021, the U.S. Army and Australian Defence Force announced that Canberra would contribute $70 million to the PrSM development program—particularly to support the development of the so-called Increment 2 PrSM, which aims to field an advanced seeker and guidance system to enable the targeting of ships and other mobile targets.29
A second army program, Dark Eagle (formerly Long-Range Hypersonic Weapon, or LRHW), is under development. Dark Eagle seeks to mate the joint U.S. Army–Navy Common Hypersonic Glide Body with a two-stage booster in the form of “all up rounds,” or self-contained, integrated, canisterized firing containers. Dark Eagle launchers will feature transportable, towed erector-launcher systems, each equipped with two missiles. The U.S. Department of Defense’s initial budget request described the primary role of Dark Eagle as providing the “Army with a prototype strategic attack weapon system to defeat anti-access/area denial (A2/AD) capabilities, suppress adversary Long Range Fires, and engage other high payoff/time sensitive targets.”30 A prototype Dark Eagle battery was slated to be fielded by the end of the 2023 fiscal year but has since been delayed to the end of the calendar year.31 Following this, the capability will transition to a program of record.32 In December 2021, Christine Wormuth, the secretary of the army, stated that LRHWs “are much more likely to be fielded on United States territory,” but that the army would be “ready, when called upon, to be able to put those kinds of capabilities in the [Indo-Pacific] region.”33 Dark Eagle is the longest range of the imminently deployable U.S. post–INF Treaty ground-launched missile systems, with a stated range of “greater than 2,775 km,” according to an army spokesperson.34 Depending on the upper bound to the system’s range, Dark Eagle may be able to strike targets within China and North Korea from Guam. For instance, many of the mainland China–based PLARF brigades with Base 61 are within 3,000–3,200 kilometers of Guam. While Beijing is substantially further, Pyongyang—a plausible target for Dark Eagle—is some 3,400 kilometers from Guam. With an ambiguous upper-bound range, Dark Eagle is likely to leave U.S. adversaries concerned about the prospects of deep strikes without any need for basing on allied soil.
A third notable ground-launched system is the Typhon Missile System, which seeks to meet the U.S. Army’s Strategic Mid-Range Fires (formerly Mid-Range Capability) requirement, slotting in between the PrSM and Dark Eagle in terms of range coverage.35 Each Typhon launcher will be capable of launching multirole Standard Missile 6 (SM-6) surface-to-air missiles (240-kilometer range) and Tomahawk Block IV/V cruise missiles (2,500-kilometer range) combining anti-air, anti-missile, anti-ship, and land-attack capabilities. Typhon launchers will feature four reloadable Mark 41 Vertical Launch Systems, identical to those used on U.S. and allied warships to operate the SM-6 and Tomahawk, which may have accelerated the development of Typhon.36 Three types of support vehicles—a battery operations center, a reloader, and a battery operations center support vehicle—will additionally be associated with the Typhon launcher. The Typhon will deploy to at least two U.S. Army Multi-Domain Task Forces assigned to the Indo-Pacific region.37 Following a June 2023 test of the system, the army announced that the system had reached full operational capability.38
Table 1. Select New U.S. Short-, Medium-, and Intermediate-Range Missile Programs (Post-2019) | |||||||
Name | Service | Type | Basing | Range | Payload | Status | Notes |
Precision Strike Missile (PrSM) | Army | Short-range ballistic missile | Road-mobile (M142 HIMARS and M270 MLRS) | 400+ km | Conventional | Prototype and developmental testing (for newer increments) | Fielding anticipated in 2023. Future increments to feature range extension up to 1,000+ km, with the use of ramjets, and capability against moving land and maritime targets. |
Dark Eagle (formerly Long-Range Hypersonic Weapon) | Army | Medium-range hypersonic glide vehicle | Mobile, towed erector launcher | 2,775+ km | Conventional | Prototype testing | Fielding anticipated in 2023. Features unpowered Common Hypersonic Glide Body on a solid propellant rocket booster in the form of all up rounds. |
Typhon Missile System (Strategic Mid-Range Fires) | Army | Multimode missile launcher (SM-6 and Tomahawk) | Towed Mark 41 vertical launch system | 240-2,500+ km | Conventional | Initial operational capability | First prototype may be fielded by the end of2023. Typhon can launch both SM-6 and Tomahawk cruise missiles from a common Mark 41 vertical launch system. |
AGM-183 Air-Launched Rapid Response Weapon (ARRW) | Air Force | Hypersonic glide vehicle | Air-launched (B-1, B-52, and planned B-21) | 1,000+ km | Conventional | Canceled | Canceled after three failed tests and one successful test. |
Hypersonic Attack Cruise Missile (HACM) | Air Force | Hypersonic cruise missile | F-15E and likely B-52, B-1, and B-21 | Unknown (likely sub-1,000 km) | Conventional | Development | The air force shifted focus to HACM following the cancellation of ARRW in 2023. |
MK 70 Mod 1 Payload Delivery System | Navy | Short-range ballistic missile | Canisterized Mark 41 vertical launch system (land- or ship-based) | 240+ km | Conventional | Development | May be capable of fielding Tomahawk cruise missiles. |
Long Range Fires Launcher | Marine Corps | Ground-launched cruise missile | Remotely Operated Ground Unit Expeditionary (ROGUE) fires vehicle | 2,500 km+ | Conventional | Development | Features a single Mark 41 canister on an uncrewed, mobile launcher. May serve anti-ship and land-attack roles. |
Source: Naval News, Congressional Research Service, Air & Space Forces Magazine, Arms Control Association, and The Drive. |
Of the three post–INF Treaty ground-launched systems meant to support the army’s long-range precision fire efforts, the Typhon is the only one with a Cold War analog in the form of the BGM-109G Gryphon GLCM; both systems featured towed, trailer-mounted launchers capable of firing four cruise missiles. Unlike the Gryphon, however, the Typhon’s missiles are not intended to carry nuclear warheads, and the Tomahawk’s long-range strike capability will be complemented by the short-range strike capability of the multirole SM-6 missile. One army official involved with the Typhon program noted that the system is capable of firing “many more missiles than a Tomahawk and an SM-6.”39 As a result, the Typhon program “will be very much proliferated across our service, probably with our allied and partner nations, because it can shoot so many [types of] weapons,” the official noted.40 The program’s flexibility also positions it to play a missile defense role. The SM-6, for instance, is capable of engaging terminal ballistic missiles at greater ranges than the Patriot Advanced Capability 3 Multi-Segment Enhancement and is undergoing testing against hypersonic threats.41
Though the U.S. Army has the broadest array of new ground-launched missile capabilities, it is not alone (see table 1). The U.S. Navy has introduced a road-mobile ground launcher for short-range SM-6 missiles that features a containerized Mark 41 vertical launch system (conceptually similar to the Typhon); the system is known as the MK 70 Mod 1 Payload Delivery System.42 The MK 70 Mod 1 may also deploy on U.S. Navy ships. One MK 70 launcher was seen on board an Independence-class littoral combat ship in 2023.43 Another notable planned Tomahawk ground launcher is the U.S. Marine Corps’ uncrewed Long Range Fires Launcher, which features a single canisterized Tomahawk missile per launcher. Like the NMESIS, the Long Range Fires Launcher uses a variant of the Remotely Operated Ground Unit Expeditionary (ROGUE) fires vehicle. The ROGUE system is designed to remain survivable through rapid mobility and, once deployed in substantial numbers, dispersal.44 With the army’s Typhon, the navy’s MK 70 Mod 1, and the marines’ Long Range Fires Launcher, the United States is expected to increase its overall production of Tomahawk cruise missiles in the coming years. Budget projections for fiscal year 2024 account for the procurement of 242 Tomahawk cruise missiles by fiscal year 2028.45
While U.S. lawmakers have authorized substantial funding for a range of missile research and development efforts that would otherwise have been proscribed by the treaty,46 questions persist about the military role of many of these systems and their basing in the Indo-Pacific. All of the earlier-discussed systems remain non-nuclear, and no U.S. plans to change that are known to exist. Given the primarily maritime geography of the Indo-Pacific as viewed from a U.S. vantage point, no assured deployment sites are available west of the second island chain. The U.S. territory of Guam—the closest at some 3,000 kilometers from China’s eastern coast—is likely to host the longest range of the publicly declared U.S. systems in development (the U.S. Army’s 2,775-kilometer LRHW), but other shorter-range systems have no concrete peacetime basing options, although regional allies might decide to host them in wartime or in a serious crisis.47
Other Conventional and Nuclear Capabilities
These new ground-launched capabilities are further supplemented by a qualitative and quantitative expansion to U.S. air- and sea-launched capabilities that were never treaty constrained in the Indo-Pacific and have long been a mainstay of U.S. power projection capabilities in the post–Cold War era. A wide array of such capabilities is currently deployed in the Indo-Pacific, and new planned systems will further buttress U.S. strike capabilities by the end of the decade. Ship-based Tomahawk land-attack cruise missiles and air-launched cruise missiles (particularly the 370-to-925-kilometer AGM-158 JASSM and its variants) confer a substantial deep-strike capability. Recent indicators further suggest that the U.S. Department of Defense is seeking to substantially increase production of JASSM/LRSAM (the 370-kilometer LRASM variant) missiles for the U.S. Air Force to as many as 1,100 per year.48 This could indicate a planned increase in the current maximum of 10,000 JASSM/LRASM units, which was itself an increase from an earlier maximum of 4,900 units that the air force had planned to procure.49 The U.S. Navy’s fiscal year 2024 budget request also indicates that production of new Tomahawk units will increase substantially, in part to support foreign sales.50
New capabilities, such as the AGM-183 Air-Launched Rapid Response Weapon (ARRW), were set to further supplement the ground-launched capabilities described earlier. The ARRW was a hypersonic air-to-surface, standoff weapon under development for the air force. The missile was expected to feature a maximum range of 1,600 kilometers with average glide speeds between Mach 6.5 and Mach 8.51 Despite a planned early operational capability date of September 2022, successive failed flight-tests delayed the program’s transition into production. A December 2022 success appeared to move the program closer to operational capability status,52 however, the U.S. Air Force ultimately announced the program’s cancellation in 2023.53 The air force is instead focusing on a hypersonic cruise missile program, known as the Hypersonic Attack Cruise Missile. This program remains in the development, test, and evaluation phase.54 The navy is additionally seeking to deploy a Conventional Prompt Strike hypersonic missile—a version of the army’s 2,775+ kilometer LRHW equipped with the Common Hypersonic Glide Body—on Zumwalt-class destroyers and Virginia-class submarines by the mid-2020s.55
Nuclear-capable nonstrategic missiles, meanwhile, have a diminished role for the United States in the Indo-Pacific and generally in the U.S. nuclear arsenal. U.S. theater-range nuclear capabilities have been limited since the end of the Cold War, particularly since the removal of U.S. deployed nonstrategic nuclear weapons in Asia pursuant to the U.S.-Soviet Presidential Nuclear Initiatives.56 Post–Cold War adjustments to U.S. nuclear posture in the course of several Nuclear Posture Reviews have not reversed this trend; instead, some post–Cold War capabilities that remained in central storage, such as the nuclear-armed Tomahawk land-attack cruise missile, were retired.57
The primary set of long-range strike capabilities based in the region continues to be conventional. These are set to potentially diversify as new ground-launched systems are developed and deployed in the aftermath of the INF Treaty’s expiration in 2019.
While the Trump administration proposed a nuclear-armed sea-launched cruise missile in its 2018 Nuclear Posture Review,58 the Biden administration chose not to endorse this capability in its subsequent review.59 The sole deployed nonstrategic U.S. nuclear-capable missiles that would be available for prompt use in the Indo-Pacific as of 2023 include a limited number of deployed Trident D5 SLBMs with lower-yield W76-2 warheads. The Trump administration’s 2018 Nuclear Posture Review claimed this system would “help counter any mistaken perception of an exploitable ‘gap’ in US regional deterrence capabilities.”60 The Biden administration endorsed the W76-2 as contributing to the “flexibility” of U.S. deterrence strategy, including in the Indo-Pacific.61 Beyond the W76-2, U.S. nuclear-capable B-52H bombers can carry as many as twenty AGM-86B air-launched cruise missiles with variable-yield W80-1 nuclear warheads.62 B-2A Spirit bombers can further carry variable-yield B61 gravity bombs. No U.S. nuclear weapons are permanently forward-based at airfields in the Indo-Pacific. The primary set of long-range strike capabilities based in the region thus continues to be conventional. These are set to potentially diversify as new ground-launched systems are developed and deployed in the aftermath of the INF Treaty’s expiration in 2019.
The Role of New U.S. Capabilities
Despite surging interest in the pursuit of ground-launched systems with short, medium, and intermediate ranges, the military necessity or even benefits of these capabilities had been inconsistently appraised. For instance, in 2017, Selva said that the United States had no military requirements that could not be satisfied “due to [U.S.] compliance with the INF Treaty.”63 Moreover, despite ongoing U.S. ambitions to hold at risk mobile targets—for instance, with successive planned increments of the PrSM—the army’s own examination of the advantages and drawbacks of long-range precision fires in its 2018 pamphlet on Multi-Domain Operations notes that these capabilities are “best suited for attacking stationary targets due to . . . long time of flight.”64 The same document notes that “naval strikes and stand-off air strikes . . . have characteristics similar to” long-range precision fires.65 Moreover, U.S. officials have offered divergent views on the appropriate numbers for new hypersonic capabilities in the post—INF Treaty period. Secretary of the Air Force Frank Kendall offered the view that hypersonic weapons, due to their higher costs compared to ballistic or cruise missiles, will likely result in “relatively small inventories” for the United States.66 During the Trump administration, by contrast, senior Pentagon research and development officials suggested that hypersonic weapons could be procured in much greater numbers, including in the “hundreds.”67
Much of the theory of how new U.S. missile capabilities—particularly, U.S. Army ground-launched missiles—will contribute to weakening Chinese A2/AD capabilities in a conflict depends on the specifics of regional basing. Some proponents of withdrawing from the INF Treaty, for instance, suggested that new U.S. missile capabilities could deny China’s conventional forces the ability to “quickly overrun America’s most vulnerable allies.”68 China’s substantial ground-based missile forces could inflict massive damage against U.S. allies and forward-deployed U.S. forces, but no new missile systems since developed by the United States could range the Chinese missiles’ launch points from currently available basing sites on U.S. territory. The U.S. Army notes, however, that its Multi-Domain Task Forces, which will be supported by new long-range missile capabilities, are designed to deliver “precision effects and precision fires . . . against adversary [A2/AD] networks in all domains, enabling forces to execute their operational plan (OPLAN)-directed roles” (emphasis added).69 This all-domain role suggests that targeting ground launchers for Chinese missiles may not be an initial priority—or that other mission sets (including anti-ship and anti-air/missile) may be a greater focus. In general, research and development efforts have proceeded apace with little specificity on basing. Senior U.S. Army officials acknowledge that basing depends on diplomatic and political factors. “The politics of where [new missiles are] based, how they’re based, will be up to the policymakers and the diplomats,” General James C. McConville, the chief of staff of the U.S. Army, said in March 2021.70 While these new missiles no doubt confer operational and tactical benefits that could contribute to the success of a future U.S. military campaign in the Indo-Pacific, the theory behind the utility of these capabilities must also contend with the political and strategic realities—and potential liabilities.
As the United States proceeds to develop and deploy these new missile capabilities, two particular issue areas will need further attention. First, as many of these capabilities qualitatively shift the nature of the non-nuclear threat to adversary nuclear forces (primarily in China but also in North Korea), new measures will be needed to mitigate the risk of unintended escalation. China is in the process of expanding the size of its nuclear forces partly out of long-standing concerns about U.S. conventional counterforce capabilities, for instance. With little clarity on the nature of the targets that may be assigned to these various new strike capabilities, Chinese decisionmakers may see no reason to believe that the United States would eschew using these long-range non-nuclear strike capabilities as part of a broader counterforce campaign. This alone could partly motivate and justify China’s ongoing nuclear stockpile expansion. Escalation concerns with North Korea, meanwhile, have rarely featured in U.S. debates on the post–INF Treaty missile force posture in the Indo-Pacific, but Pyongyang too is likely to bear similar concerns.71
A positive feature of the planned deployments of new ground-launched U.S. Army missiles is that they are all unlikely, initially, to have the capability to range deep within China, where they might otherwise hold nuclear weapons facilities, launchers, and other related infrastructure at risk.72 U.S. policymakers may seek to offer assurances to China along these lines while further underscoring that the United States would not otherwise seek to deliberately target nuclear forces with non-nuclear weapons. Though these sorts of assurances could be part of a strategic stability dialogue between the two countries, unilateral assurances can be valuable even in the absence of such a dialogue. These questions deserve particular urgency as the United States may move to devote greater value to non-nuclear weapons to cope more generally with China’s growing nuclear forces. Jake Sullivan, Biden’s national security adviser, has indicated that “cutting-edge non-nuclear capabilities,” including “conventionally armed hypersonic missiles that can reach heavily-defended, high-value targets,” may contribute to strategic nuclear deterrence as the United States faces, for the first time, two nuclear peers: China and Russia. Similar assessments concerning non-nuclear weapons of longer ranges had been offered by U.S. officials in earlier U.S. debates on global prompt strike systems prior to the U.S. INF Treaty exit.73 Beijing and Moscow are likely to interpret Sullivan’s remarks as suggestive of a potential overt future nuclear counterforce role for new U.S. regional missile systems. While this logic appears to be primarily geared at domestic opponents of the Biden administration who might otherwise favor a quantitative expansion in the size of the deployed U.S. nuclear force, greater reliance on non-nuclear systems will need to contend with the new missile dynamics at play today in Asia.74
A second matter for consideration is the potential role of arms control—or general risk reduction—in lowering the costs of peacetime military competition and the scope of a war, should deterrence fail. Unlike the background to NATO’s dual-track decision in 1979, the current theory of building up new missile capabilities rests almost entirely on buttressing deterrence of a general, regional, conventional war in the Indo-Pacific. As discussed earlier, China’s reaction to the United States’ withdrawal from the INF Treaty and its subsequent pursuit of new capabilities suggests that Beijing perceives these developments as negative for its own security interests. While China may not be eager to enter a process of formal, verified arms control initially—especially as long as it maintains a quantitative edge in theater-range missile forces—U.S. policymakers should begin to consider various arms control approaches that could bear fruit. They should simultaneously begin to explore allied perceptions concerning the role of missile forces in the region and consult on the parameters of possible arms control and risk reduction arrangements that would benefit U.S. and allied interests. Specific recommendations to this end are included in the final chapter of this report.
U.S. Geographic Constraints and Difficult Alliance Politics
The conditions driving post–INF Treaty missile development efforts in the United States today are largely incomparable to the dynamics that were at play in Europe in the 1980s, where concerns over nuclear instability and extended deterrence were paramount. A striking difference between the two cases is the role of geography. Cold War dynamics between NATO and the Warsaw Pact were centered on the continental landmass of Europe, while contemporary competitive dynamics between the United States and China are destined to play out in the vast maritime domain of the Indo-Pacific. Another difference is the fundamental asymmetry between the ground-based theater missile forces of the United States and China in Asia. This asymmetry manifested in the thirty-two years that the INF Treaty constrained the United States, a period that also saw guidance technology advances that gave theater ballistic and cruise missiles viable and substantial conventional battlefield missions that did not exist in the 1980s and were not envisioned in the treaty. As a traditionally continental military power, China invested heavily in mobile, land-based, theater-range missile forces initially for nuclear delivery, but it came to rely heavily on them (especially ballistic missiles) for conventional warfighting. The United States, meanwhile, has little territory available to base theater-range, ground-launched missiles in the Indo-Pacific—Guam is a notable exception—and its allies remain hesitant to host these missiles. As a result, U.S. naval surface warfare assets, submarines, and long-range bombers have served as the primary platforms for conventional long-range strike missions in Asia using manned aircraft and land-attack cruise missiles (not ballistic missiles).
However, for proponents of locating U.S. ground-launched missiles, both in anti-ship and land-attack roles, in Asia, the geographic realities of the region are a justification for pursuing such systems. Proponents emphasize the putative benefits of ground-launched systems, underscoring the limited missile-carrying capability of many air- and sea-based platforms and the lack of an at-sea reload capability for U.S. ship-based vertical launch systems.75 They further add that the vast distances involved in projecting power across the Pacific Ocean may mean that U.S. air- and sea-based platforms may be otherwise unfavorably postured as a serious crisis escalates into a conflict, while forward-based ground-launched systems would provide a prompt strike capability if based appropriately. While these arguments contend with some of the inherent trade-offs involved in the long-standing U.S. reliance on air- and sea-based long-range strike systems, it remains likely that, whatever the military utility of ground-launched land-attack missiles, the United States will simply lack real estate on which to base these weapons in peacetime.
It remains possible that growing threat perceptions concerning China and possibly North Korea may prompt certain U.S. allies in Asia to reconsider the possibility of opening formal consultations with the United States on missile basing.
Of the five U.S. treaty allies in Asia—Australia, Japan, the Philippines, South Korea, and Thailand—none are likely candidates for deployments of land-attack systems. Experts, analysts, and certain political decisionmakers in Australia and Japan are most positively disposed to such deployments, but they recognize the domestic political obstacles involved and have thus not publicly indicated that deployments are likely.76 As discussed earlier, both countries have instead chosen to undertake substantial investments in their own missile capabilities; these could be supplemented by U.S. capabilities. South Korea, which hosted U.S. tactical nuclear weapons until December 1991, has also shown no interest in hosting such missiles now. Seoul is particularly aware of Chinese sensitivities, recalling the harsh unofficial economic sanctions South Korea endured after the 2016 decision with the United States to deploy a Terminal High Altitude Area Defense missile defense system on its territory.77 Moreover, South Korean experts and officials see little to no role for new U.S. strike capabilities on the Korean Peninsula, emphasizing the country’s own substantial missile capabilities.78 There is interest among some officials in the redeployment of U.S. tactical nuclear weapons to the peninsula, but Biden administration officials have ruled out that prospect.79 Finally, the Philippines and Thailand are unlikely hosts for new U.S. missiles.80 Bangkok has sought improved ties with Beijing, and although the Philippines’ approach to the United States has varied substantially with changes in its government—with a particular nadir for ties with the United States under the six-year presidency of Rodrigo Duterte—Manila has shown no openness to hosting U.S. missiles.81
It remains possible that growing threat perceptions concerning China and possibly North Korea may prompt certain U.S. allies in Asia to reconsider the possibility of opening formal consultations with the United States on missile basing. Public opinion—which, for instance, is commonly cited by Japanese officials and experts as a primary inhibitor of such basing on Japanese soil—has markedly changed on defense issues in the aftermath of Russia’s invasion of Ukraine.82 Tokyo is seeking to increase defense spending to as much as 2 percent of GDP, a substantial departure from Japan’s generally limited post–World War II defense spending.83 Even if permanent basing of long-range surface-attack missiles on Japanese soil will remain challenging, some U.S. proponents have raised the possibility that such capabilities could be deployed on a rotational basis to enhance immediate deterrence in a crisis.84 Rotational deployments in a crisis, however, would be highly visible and could generate escalatory incentives for an attacker to act prior to the arrival and deployment of these capabilities in theater.85 Rotational deployments may also concede one of the core benefits of forward-deployed ground-launched missiles over their air- and sea-launched counterparts: their responsiveness and promptness. Continual rotations could obviate this problem but would introduce logistical complexities and likely result in political costs comparable to permanent deployments.
Russian Post–INF Treaty Proposals and a Return to Restraint
From Asian vantage points, the INF Treaty may seem entirely like a relic of a bygone era, but the structural role once played by the treaty continues to bear relevance in Europe, particularly since Russia’s 2022 invasion of Ukraine. In 2020, following the INF Treaty’s end, Russian President Vladimir Putin had offered a missile deployment moratorium focused exclusively on Europe. Russia was prepared to “refrain from deploying in its European part the 9M729 missiles,” a 2020 report from state news agency TASS noted, implying that the once-treaty-violating dual-capable missiles would be drawn back to Russian territory east of the Ural Mountains.86 At that time, the United States had assessed that four 9M729 battalions, featuring some one hundred missiles, had been deployed, including at least one battalion in Russia’s Eastern Military District.87 While the Russian overtures were not reciprocated initially, NATO offered Moscow assurances about its plans following the treaty’s end. As the United States withdrew from the treaty in August 2019, NATO Secretary-General Jens Stoltenberg publicly reiterated earlier NATO statements that the transatlantic alliance had “no intention to deploy new land-based nuclear missiles in Europe” (emphasis added).88
Putin had also proposed “mutual verification measures” to address ongoing Russian and NATO concerns. These measures focused on verifying both that fixed Aegis Ashore ballistic missile defense facilities in Europe could not launch offensive cruise missiles and that the Russian 9M729 missile remained nondeployed west of the Urals. The Russian proposal, however, did not accept the premise that the 9M729 was indeed a treaty-violating missile. In 2019, prior to the end of the INF Treaty, Russia had exhibited a missile it claimed was the 9M729, alleging that the missile was fully in compliance with the treaty. According to U.S. intelligence assessments at the time, the exhibited missile did not correspond to the missile that the United States had assessed as having been tested to ranges in violation of the treaty.89 As a result of this discrepancy and broader mistrust between the two sides, the United States did not seriously reciprocate Russian interest in exploring these verification measures nor a post–INF Treaty missile moratorium until the crisis leading up to Russia’s February 2022 invasion of Ukraine.
Prior to Russia’s invasion, Washington approached Moscow in early 2022 with written proposals concerning the military balance in Europe. This included broader arms control–related measures, including on missiles.90 At least one of these measures appeared to respond to Russia’s overtures in 2019 concerning a post–INF Treaty missile moratorium.91 Washington’s offer also contended with intra-NATO divergences on acceptable reciprocity measures; Poland, for instance, was more interested in inspecting Russian missile deployments in the Kaliningrad exclave.92 Nevertheless, in the weeks leading up to Russia’s invasion of Ukraine, U.S. officials emphasized that they were “open to discussing” the “future of certain missile systems in Europe along the lines of the INF Treaty.”93
The contours of what a new European security architecture might look like in the aftermath of Russia’s war in Ukraine are impossible to predict and, in any case, outside the scope of this report. However, it is not implausible that, either as part of immediate postwar negotiations or subsequent security talks, Russia and NATO may once again revisit missile-related matters. It is unlikely that an agreement resembling the INF Treaty would emerge out of such a process, particularly given the vast discrepancy in conventional precision strike capabilities between Russia and NATO that will likely be a lasting consequence of the former’s large-scale missile use on the battlefield in Ukraine. Nevertheless, any new arrangements to limit the deployment of conventional missiles in Europe could have reverberations in the Indo-Pacific, either due to Russian insistence that novel missile capabilities under development by U.S. allies in Asia be considered or the effect this might have on allowing the United States to devote additional resources to buttressing its Indo-Pacific military posture. In other words, missile dynamics in the Indo-Pacific will likely be affected by future European security arrangements.
Notes
1 “DOD Conducts Ground Launch Cruise Missile Test,” U.S. Department of Defense, August 19, 2019, https://www.defense.gov/News/Releases/Release/Article/1937624/dod-conducts-ground-launch-cruise-missile-test.
2 The complete title of the treaty is the “Treaty Between the United States of America and the Union of Soviet Socialist Republics on the Elimination of Their Intermediate-Range and Shorter-Range Missiles.” See “Treaty Between the United States of America and the Union of Soviet Socialist Republics on the Elimination of Their Intermediate-Range and Shorter-Range Missiles,” U.S. Department of State, accessed October 21, 2022, https://2009-2017.state.gov/t/avc/trty/102360.htm#text.
3 Unconfirmed press reports have suggested that Washington may open consultations with Tokyo, but no such consultations have become public. “Washington Weighing Deploying Medium-Range Missiles to U.S. Forces in Japan, Sankei Reports,” Reuters, February 5, 2023, https://www.reuters.com/world/washington-weighing-deploying-medium-range-missiles-us-forces-japan-sankei-2023-02-05.