Advances in space technology are making the extraction of lunar and asteroid materials increasingly feasible. These capabilities promise the potential for significant economic gains, greater energy security, and new avenues of geopolitical influence for any spacefaring nation capable of developing and sustaining resource-extraction operations. As competition accelerates, the question is no longer whether space mining will occur, but who will shape the rules, norms, and capabilities that govern it.

To preserve American power in space, the United States must take formative policy action and protective research and development (R&D) measures to define the future of space mining before rival nations do. Building on the strategic momentum established in the space domain during the first Trump Administration, namely the creation of the U.S. Space Force, securing an early foothold in space mining will help counter adversarial efforts to undermine American leadership and preserve space as a key frontier for American power.

Formative Policy Action in Space Mining

In emerging domains, the first actors often leave a legacy that serves as a reference point for subsequent laws and behavior, such as the Outer Space Treaty (OST) of 1967. During the Cold War, the U.S. and the Soviet Union pushed outer space beyond its initial symbolic and scientific uses. Concerns over nuclear escalation prompted the creation of a legal framework that addressed non-weaponization and restrictions on national sovereignty. Despite approaching its 60th anniversary, the OST remains a foundational pillar of outer space governance, demonstrating how proactive U.S. leadership defined the rules of engagement and established operational precedents in an emerging domain. Sustaining this proactive approach is critical if the U.S. is to seize the strategic opportunities in outer space.

Space mining is among the more recent technical opportunities to emerge, alongside satellite constellations, orbital maneuvering, and AI-enabled platforms. Yet space mining is unique in that it offers potential energy security and trillions of dollars in economic value to those possessing return-to-Earth capabilities (currently limited, forcing a focus on in-situ resource utilization (ISR) for propulsion and life support). According to NASA’s Asterank database, extracting resources from the ten most cost-effective asteroids could yield profits exceeding $1.5 trillion. The promise of energy resilience and economic gain has captured the attention of global powers and middle-state actors alike, leading to a growing number of spacefaring nations and sparking geopolitical friction.

The U.S. and Luxembourg were among the first to formalize space mining in their legal frameworks, recognizing outer space resources as property subject to ownership and commercial trade. Conversely, Russia cites the Outer Space Treaty’s designation of space as the “province of all mankind” as a basis for prohibiting resource extraction and ownership. In response to the Trump Administration’s proposed lunar mining initiatives, Russian officials went so far as to accuse the U.S. of orchestrating an “invasion” of the Moon, likening it to “another Afghanistan or Iraq.” Russia’s actions, however, contrast sharply with its public stance, given its willingness to explore an agreement on space mining with Luxembourg in 2019.

Yet American space mining laws have been relatively insulated from further international criticism because they align with formative international frameworks. For example, the U.S. Commercial Space Launch Competitiveness Act of 2015 reflects Article II of the OST, which prohibits national appropriation of celestial bodies. Additionally, the 2020 National Space Policy aligns with the Artemis Accords by emphasizing transparency in national space policies and space exploration plans, as well as the sharing of scientific information. The legitimacy of U.S. legal principles has been strengthened by demonstrating its commitment to sharing the space domain as a collaborative partner while advancing its own interests and strategic advantages.

Critical questions about access to mining sites, extraction limits, and fair participation remain unanswered because frameworks such as the OST predate the concept of space mining. Addressing these questions and providing certainty before capabilities mature or competing nations establish their own frameworks is essential to preserving a U.S. strategic advantage in space.

Protective R&D Measures for Space Mining Capabilities

As the future of space mining and its economic potential threaten to catalyze geopolitical tensions, it is crucial for the U.S. not only to be among the first to establish governance frameworks but also to develop tangible space mining capabilities. Yet space is no longer a domain of uncontested U.S. dominance, as China has evolved from a near-peer to a peer competitor. Initiatives such as the Tiangong Space Station and the International Lunar Research Station underscore China’s growing space capabilities and its ambitions to assume a leadership role.

China’s rapid rise may be attributed in part to its exposure to U.S. space technologies, as bilateral cooperation agreements have provided avenues for interaction with U.S. research and development efforts. Despite the Wolf Amendment, which prohibits bilateral cooperation with China without explicit authorization from Congress and the FBI, numerous violations of the provision have likely conferred strategic benefits on China, eroding the competitive edge the U.S. seeks to maintain. In 2024, the Office of the Inspector General investigated a state University for violations of the Wolf Amendment and announced in December that the University agreed to pay $715,580 to resolve civil allegations. When applying for and receiving NASA research grants, the University failed to disclose a professor’s affiliations with and support from the Chinese government. Similarly, according to a report published by the Select Committee on the Strategic Competition Between the U.S. and the Chinese Communist Party (CCP), hundreds of articles crediting NASA funding were identified that were jointly published by U.S. researchers (including public universities and federal research entities) and CCP institutions. In early February 2026, the University of Texas at San Antonio agreed to pay nearly $130,000 in penalties after federal investigators alleged that the lead principal investigator for a NASA-funded Center for Advanced Measurements in Extreme Environments failed to disclose affiliations with researchers in China.

China’s sustained intellectual property theft is eroding U.S. dominance in space and diminishing the impact of formative U.S. space mining policy measures. Prioritizing R&D for space mining, particularly return-to-Earth capabilities, is a central focus for spacefaring nations and must be a priority for the United States. However, R&D initiatives must be paired with enforceable oversight structures that protect intellectual property from adversarial appropriation. Enforcement entities should also demonstrate a clear commitment to implementing protective measures and punishing violators. Without such protections, any research investments risk benefiting adversarial states as much as the U.S., as evidenced by instances in which China has capitalized on U.S.-funded advancements.

Conclusion

Although the U.S. is facing increasing demands across emerging warfighting domains, with numerous competing national security concerns, space resource governance and capability development can no longer be sidelined. The U.S. must act decisively and with strategic clarity to build the legal and behavioral foundations for space mining, and to enact protections for space mining R&D, as competitors advance their own initiatives. Space mining has become a strategic imperative, one that this Administration must seize to ensure that American values, interests, and leadership define this emerging domain, resource governance and capability development resource governance and capability development.

Rachel Butler is a doctoral student in the Department of Defense and Strategic Studies at Missouri State University. She holds master’s degrees in history and strategic studies, with research interests focused on ethical and cognitive warfare. Views expressed in this article are the author’s own. 

Seizing the High Ground: The Case for U.S. Leadership in Space Mining was originally published on Global Security Review.

Recent scientific research at Sandia National Laboratories proves that carefully aimed nuclear detonations in space, early enough in an object’s approach to Earth, can deflect a threatening comet or asteroid by enough to put it on a safe trajectory. The idea is not to try to pulverize the object by a direct hit, which might still shower Earth with debris. Rather, by detonating the warhead at a modest distance from the object, the forceful ablation (evaporation) of one side of its surface, induced by the intense X-ray of a nuclear detonation, would cause the entire object to move away from the detonation.

This would be an example of what has been called a peaceful nuclear explosion (PNE). Back in the early Cold War, the US Atomic Energy Commission looked into potential applications of nuclear detonations for peaceful civil engineering purposes. These included digging canals, creating harbors, and moving mountains. And yes, fallout was expected, which is why these terrestrial applications were abandoned. An underground nuclear blast was also tested as a way to extract natural gas, by creating in some geologically promising area a subterranean cavity that could then be tapped. The test was not a success because the natural gas was radioactive.

Later, India’s first successful nuclear test (1974) was announced as a peaceful nuclear explosion, for oil extraction and mining purposes, not a weapon test. Then, in 1976, the U.S. and the USSR signed the Peaceful Nuclear Explosions Treaty, which permitted such blasts anywhere on Earth if the host country gave permission. Thus, there is some precedent for the use of nuclear devices for peaceful purposes.

Certainly, non-nuclear methods for diverting menacing space objects are possible. For instance, the National Aeronautics and Space Administration’s (NASA) test-demonstration DART high-velocity inert impactor mission was successful. But the object whose orbit was changed slightly was a very small moonlet of a slightly less-small asteroid. Other techniques being studied include attaching rocket motors to a threatening object or moving it aside via space tugs deploying giant nets. Such motors or tugs could be driven by chemical engines, or non-explosive nuclear propulsion, or solar power (either solar panels, or light sails).

These latter techniques are years or decades away from meaningful deployment. Due to their lower specific energy compared to a PNE, they would need for the inbound object to be detected very early and to be comparatively small.

For the largest potential Earth-bound objects, especially those coming from sunward, which can make them hard to detect very early, peaceful nuclear explosions might be an essential diversion method.

Obviously, such use of nuclear devices, well away from any people living on Earth or in space, would be for the benefit of mankind. However, nuclear devices can also be deadly weapons of war. They are indeed being looked at by America’s adversaries for purposes of space-based coercion and blackmail and even warfighting in space. Examples include Russia’s “Sputnuke” and China’s fractional orbital bombardment system. Effective strategic deterrence thus continues to require American preparedness and vigilance, throughout the cislunar and beyond the Moon.

However, nuclear explosives in space are truly a dual-use technology. There are already copious amounts of natural hard radiation throughout the solar system. An asteroid- or comet-moving PNE blast’s fallout would dissipate relatively harmlessly.

PNEs in space raise troubling but pressing questions about the need to rethink and update the Outer Space Treaty, since it prohibits placing any nuclear devices anywhere in space. On the one hand, all nuclear weapons based on-orbit should continue to be forbidden. But on the other hand, the same warheads used to defend Earth against space rocks simply must be allowed.

This might be achieved in one of two ways. One is to create a “Planetary Defense Guard” under the auspices of the UN, with the necessary nuclear devices put under UN Security Council control. However, the UN does not have a record of success regarding cooperative use of nuclear devices. A proposed plan in the early Cold War called for all nuclear arms to be pooled under central UN control. It went nowhere. The modern UN attempt at a treaty banning all nuclear devices everywhere (including PNEs) is also going nowhere, for the same reason. States owning nuclear warheads have no desire to give them up.

The other way to get the protection Earth requires is to recognize that planetary defense is a necessary and unavoidable aspect of the “Scramble for the Skies” now emerging. In this alternate scheme, rival powers compete using nuclear devices in a peaceful way for space-based civil engineering purposes. They vie to develop the best suite of proprietary systems, procedures, and technologies for deflecting Earth impactors via peaceful nuclear explosions. They could then also “race” to launch them whenever actually needed. Such healthy competition might significantly increase the odds of at least one contender making a successful diversion, while letting all contenders participate in this ultimate “space Olympic decathlon.”

Changing the OST out of sheer necessity, to allow PNEs for planetary defense, would have several very significant societal benefits. It would more rapidly and effectively advance humanity’s space defenses. It would urgently accelerate everything needed for the successful commercialization, industrialization, and colonization of space, which advocates say could take pressure off Earth’s endangered environment, too.

Allowing PNEs in space would also give spacefaring nuclear powers a way to stay within Cold War–style safety guardrails against nuclear crises and nuclear war. It would allow them to instead compete to show their culture’s and their government’s superiority through the peaceful, beneficial harnessing of both spaceflight and nuclear energy. Such a grand competitive program would help address three existential threats to the human race at once, three possible extermination events: a large asteroid strike, a climate catastrophe, and a nuclear holocaust.

Joe Buff is a Senior Fellow at the National Institute for Deterrence Studies.

Nuclear Devices in Space was originally published on Global Security Review.

India’s anti-satellite (ASAT) test, held on March 27, 2019, highlights its growing space capabilities and intent to weaponize space. India’s test, known as “Mission Shakti,” demonstrated its ability to intercept and destroy a satellite in low Earth orbit, positioning India as one of only four countries with such capabilities. While Indian officials maintain that the test was aimed at strengthening national security and not directed toward any particular country, such a capability would pose a significant threat to Pakistan’s space assets, which would undermine Pakistan’s situational awareness, communication, and command-and-control capabilities during a conflict.

The implications of India’s recent MIRV test to its intent in the space domain have received little scrutiny, with one Indian analyst suggesting that the country’s MIRV efforts complement its space ambitions. However, analysts did not address the potential implications on regional stability. India’s development and testing of advanced missile technologies suggest that New Delhi could use these capabilities for counter-space missions, including the targeting of satellites, and their expansion of counter-space weapons may disrupt the strategic equilibrium in South Asia.

Bringing MIRVs to Space

While the primary use of MIRV ballistic missiles is not in counter-space missions, there are scenarios and technologies related to MIRVs that could potentially be adapted for anti-satellite (ASAT) roles. Instead of carrying nuclear warheads, the MIRV could be equipped with kinetic kill vehicles (KKV) or other payloads designed to disable or destroy satellites through collision or other means. A missile equipped with MIRV technology could launch multiple payloads into space, each with its own propulsion and guidance systems, allowing them to maneuver into specific orbits close to target satellites. Moreover, the independent targeting capability of MIRVs means each payload could be directed to a different satellite, potentially allowing for simultaneous attacks on multiple targets in different orbits.

In addition, co-orbital systems can loiter in space and potentially engage targets when needed, providing a persistent threat compared to direct-ascent ASAT systems. MIRVs could be adapted for co-orbital ASAT missions by modifying their payloads and utilizing their independent targeting capabilities. Russia and China have demonstrated co-orbital ASAT systems, while the United States maintains advanced space technologies that could potentially be used in similar roles. The adaptation of MIRVs for such purposes would be complex and carry significant strategic and legal implications.

Implications for Regional Stability

Outer space is considered a global common, a concept established by the Outer Space Treaty of 1967, which ensures that space is free for exploration and use by all countries, cannot be claimed by any nation, must be used for peaceful purposes, and should be preserved for future generations. It is crucial that this principle should be consistently applied to preserve space for the benefit of all states for communication, navigation, weather monitoring, and scientific research. However, the growing overlap between military and space technologies is blurring the lines between these fields and raises apprehensions about the militarization and potential weaponization of the domain.

The advancements made by India in military technology and satellite capabilities, which integrate military and space capabilities, have raised significant concerns about the weaponization of space in Pakistani policy circles. Pakistan also tested a MIRV capability on its Ababeel missile. However, it never demonstrated its intent to develop counter-space weapons through policy or capability development. Pakistan’s space policy and activities are focused on peaceful uses of outer space, such as satellite communications, remote sensing, and scientific research. Islamabad has participated in international initiatives aimed at promoting the responsible and peaceful use of outer space, including discussions on space security and arms control within forums such as the United Nations Committee on the Peaceful Uses of Outer Space (COPUOS).

Considering India’s development and modernization of its military beyond traditional security needs, such as its ASAT capability and advanced missile ranges, there is a possibility that New Delhi may use MIRVs for counter-space missions in the future. In a scenario of escalating tensions with Pakistan, India could conduct counter-space missions by either placing co-orbital ASAT systems during a brewing crisis or launch KKVs during a conflict by using MIRV capability. This would enable India to destroy Pakistani satellites, severely impairing Pakistan’s situational awareness, disrupting secure military communications, and degrading command-and-control functions.

As New Delhi strengthens its counter-space capabilities, its potential development of counter-space capabilities can upset the balance maintained by Pakistan’s effective deterrence posture in South Asia. The complex interplay between nuclear and conventional forces maintains this balance. However, there is a growing asymmetry between India and Pakistan in space capabilities.

New Delhi’s substantial advancements and investments in space technology and infrastructure outmatch Pakistan’s space capabilities, creating a significant power disparity where India has a much greater capacity to deploy and utilize space-based assets for various purposes, including military and intelligence gathering. India’s disproportionate expansion of space capabilities not only poses a threat to Pakistan but also China. Their reliance on satellites for command, control, communications, computers, intelligence, surveillance, and reconnaissance (C4ISR) functions is growing to address genuine security needs. Pakistan recognizes the strategic importance of information superiority in modern warfare.

With evolving security challenges, including border surveillance and counter-terrorism operations, Islamabad is enhancing its C4ISR capabilities through significant technological upgrades such as satellite programs and advanced communication systems, along with the integration of centralized command centers and secure communication networks. The expansion includes increased use of drones for surveillance and reconnaissance, development of electronic warfare capabilities, and robust cybersecurity measures.

Human resources are being developed through specialized training and international collaboration, particularly with China and Turkey, to facilitate technology transfer and interoperability. These efforts aim to improve situational awareness, decisionmaking, and operational effectiveness, strengthening Pakistan’s overall national security.

During a crisis, Pakistan may face the risk of its satellite assets being targeted which could have significant impact on its military and strategic capabilities. Pakistan could face severe constraints in its C4ISR capability. Moreover, the integration of satellite communication into Pakistan’s drone operations and C4ISR framework highlights the dependence on these assets for maintaining robust communication. Hence, the loss of satellite communication could disrupt command-and-control functions, impairing coordination and timely decisionmaking across the armed forces.

In view of these reasons, it is possible to conclude that India’s MIRV test represents a dangerous shift in the domain of space weaponization. The integration of MIRV technology with India’s missile systems not only enhances its nuclear deterrence but also signals its potential use for counter-space capability. Therefore, while India’s achievements in missile technology and space capabilities are notable, they carry significant risks for regional stability.

Maryyum Masood is working as a Research Officer & Associate Editor at the Center for International Strategic Studies (CISS) Islamabad. She is an MPhil scholar in the Department of Strategic Studies at the National Defense University (NDU) Islamabad. Views expressed in this article are the authors own.

India’s MIRV Development – A Latent Counter-space Capability was originally published on Global Security Review.

Russia’s coercive but indiscriminate “Sputnuke” concept lies at one end of a spectrum of potential space-based nuclear weapons. The remainder of the spectrum also offers significant offensive capabilities that could make space a very difficult place for the United States.

Prepositioning nuclear weapons in space would violate the Outer Space Treaty (1967). However, Moscow or Beijing gain significant coercive capability against the United States should they move forward with such a capability.

At least three classes of nuclear weapons could, potentially, be based in orbit. Any such weapon is likely to be disguised as some non-military type of spacecraft.

The first class of nuclear weapons in space are those in low Earth orbit. They are detonated from a position where they can disable adversary satellites. One or a small number of devices could create a wide-ranging electromagnetic pulse, which, by disabling satellites, could also cause an immense zone of debris along with a longer-lasting cloud of high-energy charged particles.

The combined effects would likely degrade this region of space for an extended duration. Spacecraft transiting low Earth orbit would also face the risk of a collision with orbiting debris.

Moscow or Beijing, if at a serious disadvantage to the United States during a conflict, may “escalate to win,” setting off nuclear weapons to wreak as much havoc in space as possible. This “scorched space” tactic would seek to level the playing field and slow American efforts to both mobilize force and command and control those forces.

The second class of nuclear weapons in space are those used for ground attacks. If, for example, intercontinental ballistic missile reentry vehicle-like weapons were covertly stationed on-orbit, their launch would be difficult to track. Such a weapon placed in low Earth orbit would strike a ground target in a matter of minutes.

Third are fission reactors based in orbit to power directed-energy weapons firing microwave, infrared, or optical laser beams. These travel at the speed of light, simplifying fire control. Out in the vacuum of space, a directed-energy beam would not suffer blocking or bending due to smoke, clouds, or atmospheric refraction.

With their reactors generating power, they do not need conspicuous and vulnerable solar panels. Firing energy pulses, they do not use chemical propellants or kinetic projectiles, and so do not run out of ammunition. Their fissionable fuel can last decades.

Their pinpoint, medium-power beams could at least temporarily blind or cripple soft or semi-hardened satellites over tremendous engagement ranges, and with much less collateral damage than a nuclear blast or conventional anti-satellite weapon. A small constellation of these systems could give Russia or China offensive and defensive coverage. Fortunately, there is no evidence either adversary is developing such a weapon at present.

Current and future American presidents are unwise to dismiss the dangers posed by these different classes of space-based nuclear weapons. To deter adversaries, in some cases, rough parity via on-orbit basing may be required.

For spaced-based nuclear weapons targeting American and allied satellites, the United States’ dominance in space-based surveillance, reconnaissance, and communications make space-attack attractive. Should the United States perfect ballistic missile defenses and integrated air and missile, launching nuclear weapons from space toward ground targets may also prove an attractive option.

In many respects, the above discussion is prospective in contemplating how Russia and/or China might use nuclear weapons in space, but it is far from science fiction. For Western defense analysts, playing the part of futurist is a proactive approach to protecting American vital interests. Congressman Mike Turner’s open concern over intelligence suggesting that Russia may place nuclear weapons in space is only one example of Russian interest in weaponizing the domain.

The United States understands Chinese capabilities less well than those of Russia and their plans are even more difficult to predict. This leaves President Biden and his successors in a difficult position in the years ahead. Space is certainly a domain that will see weaponization sooner rather than later. For Americans, the question remains, who will dominate space?

 Joe Buff is a risk-mitigation actuary researching modern nuclear deterrence and arms control. The view expressed in this article are the author’s own

To Deter in Space, the US Needs On-Orbit Parity was originally published on Global Security Review.