Integrating Emerging and Disruptive Defense Technologies – Center for European Policy Analysis

Today’s race for technological supremacy is contested across multiple domains and moving at breakneck speed. The US and Europe must win.
The twenty-first-century race for technological supremacy is contested across multiple domains and moving at breakneck speed. Today’s innovators will own tomorrow’s future. As it stands, the North Atlantic Treaty Organization (NATO), the European Union (EU), and like-minded nations risk falling permanently behind. To win this race, the West must develop a common approach to integrating emerging and disruptive technologies (EDTs). The Center for European Policy Analysis (CEPA) led a year-long study to produce a transatlantic strategic framework for competing in defense and dual-use technologies. The project aims to raise awareness, spark discussion, and provide a shared framework for cooperation on these issues among NATO, EU, and national government officials, as well as industry leaders. Ultimately, it seeks to spur the development of a transatlantic defense technology strategy for the US and Europe, which will be critical for the West in light of rapid advances by Russia and China.
The study makes three important contributions to the ongoing debate. First, it offers a clear, replicable methodology to identify and prioritize critical technologies as they emerge. Second, it sets forth nine core pillars to form the basis of a common transatlantic policy framework for defense tech issues. Third, it outlines short-term recommendations to implement the policy framework. Together, these elements comprise a compelling strategy for enhancing transatlantic cooperation in defense technologies.
Governments should educate civil servants and military officers on tech issues earlier in their careers and provide realistic pathways to use these skills as they move up the value chain. Governments should provide more opportunities for civil servants and military officers to undertake short-term assignments in tech companies and vice versa.
Since the end of the Cold War, the US and its NATO allies have enjoyed a capability advantage over state and non-state adversaries. ² This advantage gap, however, has drastically shrunk in recent years. While the US and its allies spent the last two decades prioritizing counterterrorism capabilities over innovative near-peer technologies, Russia and China have been utilizing EDTs to close their traditional capability gap with NATO. These technologies – such as autonomous systems – do not seek to simply mirror NATO capabilities, but instead mitigate or even leapfrog them. As a result, NATO is no longer the main driver of new defense technologies and has fallen behind its competitors in key emerging technology areas. ³
To maintain their strategic edge in an increasingly contested world, NATO and EU nations must collaborate to leverage EDTs to enhance shared security and better prepare for future crises. Particular attention must be paid to near-term, dual-use, transformative technologies, which are rapidly affecting and overturning traditional defense methods. The ability to develop and deploy these game-changing technologies more effectively than China and Russia will shape the global role of the transatlantic Alliance in the coming decades. Allies are waking up to the need to forge a common approach to defense technology, but the window to act is narrowing.
Two major challenges inhibit a common approach. First, NATO and EU member states are each focused on somewhat different technologies, while innovating and investing at radically different levels and speeds. Recent priority lists and policy efforts, such as NATO’s DIANA and the Hub for EU Defence Innovation (HEDI) within the European Defence Agency (EDA), ⁴ have rightly sought to address this and hold important potential to help the Alliance pursue EDTs to transformative ends. ⁵ Still, insufficient coordination over time among nations and institutions has produced duplicative efforts, inefficient spending, and a concerning interoperability gap, most acutely between the US and European allies. Second, Euro-Atlantic allies diverge on key policy issues surrounding the defense application and adoption of EDTs, such as implementing common technology governance structures and managing supply-chain issues. The result is slow and stilted decision-making that impedes the Alliance’s ability to ideate, develop, and deploy defense technologies quickly enough to compete with Russia and China. These dynamics undermine NATO’s collective defense, internal cohesion, and strategic edge over Russia and China.
To address these issues, CEPA has undertaken a year-long study to set forth three elements that are missing from current literature and policy debates: 1. A systematic ranking of key defense technologies to prioritize that will give the Alliance as a whole the most strategic “return on investment” and elevate its competitive edge; 2. A common framework for addressing policy issues around EDT development and integration; and 3. A list of concrete steps toward these ends for NATO and EU member governments to take in the near term. This project will have immediate policy relevance for Euro-Atlantic government officials, helping to spur discussion, unite thinking, and motivate the development of a transatlantic strategy for defense technology.
The project’s methodology primarily involved qualitative analysis through literature research, interviews, and consultations with dozens of officials and experts across national governments, NATO, the EU, industry, think tanks, and academia. ⁶ This included field visits to Brussels, London, Paris, and Washington, DC to examine areas of divergence and convergence across Euro-Atlantic countries, institutions, and companies. To inform the study and gather critical feedback, the research team at CEPA also led two workshops and two red-teaming sessions with officials, scholars, and practitioners working on these issues. CEPA also presented the initial findings of this study at the 2022 Munich Security Conference.
To examine current gaps, identify solutions, and forge a sustainable path forward, this study proceeded in three phases. First, the research team assessed priority technologies through an organically assembled EDT Innovation Matrix, which ranks EDTs that the overall alliance should prioritize based on five key factors (time, need, cost, policy challenges, and impact). The assessment’s scope was confined to dual-use technologies, which are least understood and most contested within the Alliance, and yet extremely valuable and practical, given their diverse applications. Dual-use capabilities have the benefit of consistent potential revenue from defense organizations, coupled with the accelerating impact of commercial funding, which makes them most viable. More specifically, the assessment examined such technologies with near-term application timelines (i.e., currently deployed or will likely be deployed within five years), which are most relevant for immediate NATO and EU planning. This study also assessed the Alliance’s capabilities as a whole, with supplemental analysis of comparable Russian and Chinese capabilities to understand NATO’s threat environment.
Based on these parameters, the research team identified and assessed five technologies as top priorities for the Alliance’s strategic edge: space-enabled capabilities, unmanned systems, hypersonics, edge computing, and cognitive influence capabilities. ⁷ These were selected due to NATO’s relative need ⁸ based on the current and foreseeable threat environment as well as Russian and Chinese capabilities in those areas, feasibility for realization, and the transformative potential of these technologies to impact the Alliance’s capabilities as a whole vis-a-vis China and Russia in future warfare. As explained in this section of the paper, the research team decided not to focus on artificial intelligence and machine learning (AI/ML) due to the extensive research, analysis, and literature that already exists and the fact that the authors fundamentally view AI/ML as a key enabler for all the above EDTs, rather than as a standalone capability. For further discussion, there is an additional section on excluded technologies later in this paper.
Second, the research team developed a common strategic framework to address policy divergences by formulating nine key policy pillars to guide transatlantic defense tech cooperation. Third, the researchers set out next steps for policymakers. This component of the project includes 50 short-term, concrete recommendations under each policy pillar to help nations and institutions implement the strategic framework. Finally, the research team developed a conceptual roadmap that includes one-year, three-year, and five-year key performance indicators (KPIs) to provide quantitative indicators to measure progress in implementing these recommendations as they evolve. It should be noted that the roadmap and KPIs which feature in appendix 1 of this paper represent only a working concept that will require further development and refinement over time.
This project was designed to have immediate policy relevance for NATO and EU member government officials, helping to spur discussion, unite thinking, and motivate the development of a transatlantic strategy for defense technology. The assessment’s five-factor EDT matrix provides a consistent and replicable process that transatlantic policymakers can use to reassess priorities as new technologies emerge. The assessment will offer compelling data for why these technologies should be prioritized, providing a pragmatic basis to drive further Allied consensus around these priorities in the future. The findings of the assessment seek to inform future defense strategies, budget decisions, and investments in Allied capitals and Brussels. The study’s strategic principles for a common policy framework will provide a foundation and shared language for Allied leaders to bridge divergences between US and European tech policies. By outlining a list of short-term policy recommendations in support of the framework, the study also provides a clear roadmap for Allied government officials to harness defense technology to strengthen NATO’s collective defense and strategic edge for the years to come. 
In recent years, EDTs have quickly become integral to discussions about strategic competition and future warfare. As these technologies have advanced and proliferated, transatlantic policymakers and defense planners have begun to recognize the importance of these capabilities to the West’s strategic edge over its adversaries and competitors. While the term “innovation” has become ubiquitous, making its way into nearly every speech, strategy, and policy document, Euro-Atlantic nations and institutions have much work to do to effectively harness EDTs for collective defense and deterrence. Undoubtedly, the transatlantic community has made significant, rapid progress over the last three to five years to this end. However, significant gaps in progress remain due to a confluence of factors. To adequately understand and address these challenges and chart the way ahead, recent progress and remaining issues are explored below.
After the Cold War, the US, NATO, and the world at large shifted focus to combating terrorism and capacity building in fragile states. ⁹ As a result, the urgency to develop and field new systems to combat potential near-peer competitors eroded. Without this motivation, NATO and its allies – especially larger ones – continued to develop and acquire complex, bespoke platforms which assumed permissive operating domains, such as billion-dollar satellites, multi-billion-dollar aircraft carriers, and GPS-dependent ground and air assets. This approach yielded incrementally better capabilities, but no truly game-changing technologies. ¹⁰ Concurrently, several of NATO’s largest allies drastically cut funding to their militaries and defense sectors, severely degrading previously robust capabilities. While this approach was sufficient for fighting technologically inferior non-state actors in the global war on terror, it has left NATO vulnerable in today’s renewed era of great power competition with Russia and China. ¹¹
In the meantime, Russia and China have taken advantage of NATO’s pause in defense innovation to develop differentiated and comparatively more cost-effective area denial capabilities designed to mitigate NATO’s traditional strengths. Over the last decade, China has risen as a scientific and technological powerhouse, while Russia has more creatively and assertively pursued asymmetric advantages. Both the Kremlin and the Chinese Communist Party (CCP) have invested in innovation programs and EDTs that are beginning to change the character of modern warfare to their benefit. ¹²
Leveraging their highly centralized systems of government, Russia and China have facilitated cooperation between defense and commercial establishments to develop technologies that have already proven advantageous across military and civilian contexts. Because these authoritarian states can mobilize all elements of national power toward their technological goals, they have moved much faster than NATO or the EU, which comprise several sovereign nations bound by slow-moving, transparent, democratic, and open-market processes. China, and to a lesser extent, Russia have made major strides in artificial intelligence, military robotics, and autonomous systems, for example, which lower the cost and operational risk for Russia and China in a potential fight against NATO, whose greatest advantages are high-end, complex capabilities with high opportunity costs for their usage (e.g., manned aircraft carriers). ¹³ This has significant implications for NATO as a whole, creating operational challenges and rapidly narrowing its traditional capability gap. Beyond these technologies, there are several key areas where Russia and China individually have managed to gain parity or even exceed NATO capabilities or develop tools to mitigate NATO advantages. Most notably, this includes hypersonic and anti-satellite (ASAT) weapons or counter-space capabilities. ¹⁴
Russia and China have developed and deployed hypersonic cruise missiles (HCM) ahead of the US and other NATO nations. In Europe, Russia has created similar anti-access area denial (A2AD) bubbles over key areas near the Baltic and Black Seas that would restrict NATO’s navigation and operation in those critical regions. Its hypersonic weapons, such as the 3M22 Zircon, can fly so fast and low that they can penetrate NATO’s traditional anti-missile defense systems and leave insufficient time for Allied response. ¹⁵ These weapons provide Russia with a means of contending with NATO’s size, mass, and key capabilities like aircraft carriers. However, some of the limits of Russia’s military and technological capabilities have been revealed by its failures during the war in Ukraine. ¹⁶ China, in particular, has ramped up investment in hypersonics to develop enhanced A2AD bubbles which would prevent the ability of the US and its allies to project power in an expanding area. ¹⁷ The proliferation of China’s HCM arsenal is intended to mitigate the US’s blue-water navy advantage. An array of carrier-killer weapons such as the DF-26 and CH-AS-X-13, at a cost of less than $100 million can disable or even, in the event of multiple strikes, sink a $13.3 billion US aircraft carriers with over five. ¹⁸
ASATs have similar, but even farther-reaching implications. NATO capabilities are highly reliant on space-enabled capabilities including GPS, satellite communications, and geospatial intelligence for situational awareness, conducting operations, and engaging in conflicts. Without these, the ability to understand the battlespace, coordinate, and react is completely disrupted. Knowing this, Russia and China have separately developed and successfully tested ASATs multiple times over the last fourteen years to counter NATO in space. ¹⁹
These weapons pose a threat to commercial, civil, and defense assets ranging from telecommunications to the International Space Station to bespoke intelligence satellites. In the latter case, a $60 million ASAT from Russia or China can readily destroy $2 billion in national security satellites, for example. Further, as ASATs are used, particularly if on low-earth orbit (LEO) based satellites, they significantly increase the chance of a cascading effect, which could destroy dozens or even hundreds of satellites, functionally turning LEO into a dead zone. ²⁰ This would be an economic catastrophe for the West (and the world at large). It would also render most, if not all, of NATO’s space capabilities inoperable, leaving the Alliance operationally deaf and blind.
Nevertheless, in some ways, tight government control has stifled radical innovation in Russia and China, compared to Western countries that encourage creative thinking, dissent, and risk-taking. In fact, to compensate for shortfalls in indigenous innovation, both Russia and China have orchestrated cyber espionage, hacks, and intellectual property theft from NATO countries in order to reverse engineer their own version of key EDT capabilities. ²¹ At the same time, their authoritarian approach has allowed the Kremlin and the CCP to actively set spending priorities, manipulate talent programs, promote national champion companies, and accelerate the development and deployment of EDTs more effectively than the free market, open systems in the US and NATO countries. ²²
Unlike NATO Allies, Russia and China have also avoided constraining their innovative efforts by establishing ethical standards, legal principles, and political consensus around tech governance. Development of technology based on shared democratic values is key to ensuring that the deployment of such technologies does not undermine the strategic standing of democracy on the international stage. However, the development of such technology requires a proactive and deliberate approach to ensuring that these values are upheld. How they are to be integrated into EDTs requires prioritizing them as early as possible in the tech development cycle to ensure final products inherently embody democratic values in a way that allows them to quickly and effectively be deployed.
Looking ahead, Russia’s defense innovation efforts will likely suffer gravely as a result of its unprovoked war in Ukraine, which is ongoing at the time of writing, as well as the increasing pressure from Western sanctions that are severely damaging Russia’s economy and defense industry. While the longer-term impacts of these dynamics on Russia’s overall military and technological capacity are not yet fully understood, this creates a larger window for NATO to elevate its own technological edge. Chinese state-driven innovation efforts, however, are set to expand, intensifying the growing techno-strategic competition between Beijing and the transatlantic alliance. To ensure China does not continue to disrupt this competition in its favor, the transatlantic alliance must work together to boost cooperation on defense tech issues.
Over the last few years, US and European officials have recognized the need to cooperate around EDTs to enhance collective defense and more effectively compete with Russia and China. ²³  NATO, for its part as the premier collective defense forum for Euro-Atlantic allies, has moved remarkably quickly to sharpen its focus on technology. It has emphasized EDT-related issues through its public messaging, ²⁴ collaboration with think tanks and civil society, ²⁵ and the 2030 reflection process. ²⁶ In the past three years, NATO has also devised an EDT strategy, released a major report tracking defense tech trends, ²⁷ boosted projects through the Innovation Hub at Allied Command Transformation (ACT), ²⁸ and released the first comprehensive AI strategy for the Alliance in October 2021. ²⁹ Perhaps most notable has been the creation of NATO’s Defense Innovation Accelerator for the North Atlantic (DIANA), whose chartered goals are to “harness new academic, commercial, and entrepreneurial start-up technology; test and develop it as potential defense capability; and connect it more quickly to military end-user operational requirements.” ³⁰ DIANA is intended to operate alongside the NATO Innovation Fund, the world’s first multi-sovereign venture capital fund slated to invest 1 billion euros in early-stage startups and other investment funds developing dual-use technologies relevant to NATO. ³¹
The Madrid Summit in June 2022 built on this progress, as the Alliance focused on the Russian threat, enhancing capabilities, and, most critically, on EDTs to aid in doing so. This EDT focus was underscored in its new Strategic Concept, released at the Summit. The Strategic Concept states: “Emerging and disruptive technologies bring both opportunities and risks. They are altering the character of conflict, acquiring greater strategic importance, and becoming key arenas of global competition. Technological primacy increasingly influences success on the battlefield.” ³² Russia’s actions in Ukraine have brought a new sense of urgency to the Alliance and highlighted the need to focus on EDTs to support the mission of deterrence and defense in Europe. The Concept places particular emphasis on space, not only as a critical technology area but more explicitly as a “warfighting” domain. Prior to 2019, NATO had avoided characterizing space in this regard in all policy documents. NATO’s new strategy clearly places emerging tech as a core element of its approach to the current and future security environment.
While NATO has a critical role to play as the core transatlantic defense organization, it is important to recognize the EU’s litany of complementary resources and mandates related to funding, regulation, and legislation around EDTs. These have also had a massive impact on the innovation ecosystem in Europe. The EU operates entities such as the European Defense Agency (EDA), European Defense Fund (EDF), Permanent Structured Cooperation (PESCO), and more that complement NATO’s mission. It has also developed its own technologies roadmap, ³³ aimed to create synergy between various European defense, civil, and space industries. Importantly, the EU recently launched the Hub for EU Defense Innovation (HEDI) ³⁴ within the EDA. ³⁵ The EU-US Tech and Trade Council, established in June 2021, also provides a transatlantic forum to coordinate on technology and related economic policies rooted in shared democratic values. ³⁶ Additionally, NATO-EU collaboration on projects such as the European Centre of Excellence for Countering Hybrid Threats ³⁷ and the publishing of various joint declarations identifying emerging tech as a key area of collaboration for the two organizations prove the utility and necessity of working in tandem on these issues.
Aside from NATO and EU efforts, individual nations have also played a crucial role in advancing EDT and innovation initiatives. Various countries have prioritized technology as part of their own national security, having developed their own national EDT and AI strategies, as well as defense accelerators. A few examples of emerging national defense accelerators within NATO include but are not limited to: the British Defence and Security Accelerator (DASA), ³⁸ the Portuguese Department of Innovation and Transformation (DIT), ³⁹ the Spanish Centre for the Development of Industrial Technology (CDTI), ⁴⁰ the French Defense Innovation Agency (AID), ⁴¹ the Leonardo-funded Italian Business Innovation Factory (BIF), ⁴² and the nascent German Accelerator. ⁴³
Beyond this, some nations have also created several multilateral frameworks, such as the French Canadian-led Global Partnership on AI, and the US-led AI Partnership for Defense, which bring together willing and capable nations to coordinate on certain issues or technologies. ⁴⁴ The trilateral partnership between Australia, the United Kingdom, and the US (AUKUS), which was established in 2021, has talked of “accelerat[ing] respective defense innovation enterprises and learn[ing] from one another, including ways to more rapidly integrate commercial technologies to solve warfighting needs.” ⁴⁵ AUKUS has announced specific cooperation on AI, cyber, autonomous vehicles, quantum computing, and hypersonic capabilities moving forward. ⁴⁵ Each of these platforms are useful in their own right and could benefit from NATO and the EU joining to add their institutional weight. The risk with the current approach, however, is the rapid fragmentation of transatlantic efforts on EDT. If this trend continues, the result could be a diffused smattering of multilateral frameworks, each focused on a particular tech issue with a different small group of countries.
Despite this progress, much work remains to be done to ensure these new initiatives are effectively implemented, remain coordinated and largely complementary across several nations and institutions, and receive adequate resources, staffing, and empowerment. Otherwise, these efforts risk appearing as innovation theater — i.e., giving the appearance of innovation through rhetoric and surface-level efforts — as opposed to fundamental organizational change. What is desperately needed is a coordinated transatlantic strategy for competing in defense technologies.
In achieving this, part of the challenge for the Alliance is that transatlantic governments are no longer driving R&D spending for EDTs. For example, compared to the late 1980s, when US Department of Defense (DoD) R&D and business R&D were nearly equal, business R&D is now over four times greater (see graph). ⁴⁶ This has left DoD, and other governments of NATO member states, incapable of setting the pace for the private sector’s innovation priorities. ⁴⁷ By comparison, Russia and China, through their state-driven innovation efforts discussed above, have managed to mobilize the entirety of their military and civilian sectors and all elements of national power to set technological priorities and rapidly achieve key advancements. As a result, NATO has begun falling behind in key emerging technology areas.
As Allied governments work to regain their collective advantage over Russia and China, there are two, multi-faceted challenges in developing a transatlantic approach for defense technology.
First, NATO and EU member states are each focused on somewhat different technologies, while innovating and investing at radically different levels and speeds, with no central authority or coordinating function for all relevant stakeholders. To remedy this, NATO and the EU have worked to align their members’ tech priorities, with each organization outlining their overarching focus areas. NATO’s include AI, data and computing, autonomy, quantum-enabled technologies, biotechnology and human enhancements, hypersonic technologies, space, novel materials and manufacturing, and energy and propulsion. The EU’s key enabling technologies include advanced manufacturing, advanced materials, life-science technologies, micro/nano-electronics, and photonics, AI, and security and connectivity. The differences between these lists are understandable due the different core missions of NATO and EU. However, both should look for synergy to collaborate on common technologies of interest.
Beyond this, various Euro-Atlantic states have their own priority technologies lists catering to differing national needs, some of which overlap with the NATO and EU lists, as well as with the lists of other nations. The creation of these lists, even if not completely identical, is an important step that illustrates political will among allies to work together on defense innovation. Nevertheless, because there is no central political, financial, or legal authority to fully harmonize and enforce a focused, single set of shared priorities across all these actors, the result is by and large a patchwork of broad defense innovation efforts. ⁴⁸
Adding to this lack of a single shared list is the reality that nations are innovating at drastically different levels and speeds based on budgets, talent, industrial and legal capacities, economic interests (which are often competing), and the maturity of each national innovation ecosystem. For instance, according to European Union (EU) innovation scores, Denmark performs 20% higher than the EU average, while Bulgaria performs well below 50%. ⁴⁹ These scores are based on ten key dimensions ⁵⁰ that provide a comparative assessment of research and innovation performance across EU members, the majority of which are also NATO Allies. The discrepancies revealed in this assessment underscore the difficulty in establishing shared defense tech priorities and getting allies to direct similar levels of resources in the same direction.
This is why NATO and the EU have established several common funds and other mechanisms to pool resources in pursuit of shared defense tech projects. ⁵¹ However, even when countries channel proportionate resources toward similar technologies, they may not necessarily focus on the same use cases, which further slows progress. This is particularly relevant across autonomous systems and space capabilities, where allies have developed new hardware for different use cases, and where they could have leveraged common platforms or buses. In short, while the Alliance may have a general list of some commonly prioritized technologies, it still lacks sufficient shared technology goals, desired end states, and specific common use cases (like those proposed as part of the 2021 NATO AI Strategy), as well as a way to enforce and implement them. ⁵²
Second, Euro-Atlantic allies diverge, most severely between the United States and Europe, on key policy issues surrounding the defense application of EDTs, such as technology governance, data-sharing, and supply-chain issues. ⁵³ The lack of a common policy framework impedes the Alliance’s ability to ideate, develop, and deploy defense technologies quickly enough to compete with Russia and China. Further, export controls (such as International Traffic in Arms Regulation) and data and hardware restrictions among allies prevent the development of a coherent, streamlined allied defense industrial base. These dynamics thus erode internal cohesion inside NATO and the EU and prevent the Alliance from setting a clear path to elevate its strategic edge. Additionally, it results in duplication of effort across the Alliance.
In an environment of strategic competition, transatlantic defense investment must do far more to reduce duplication and maximize return on investment (ROI). Although steps taken by NATO to develop a common strategic approach is a great step forward, more is needed to bring coherence to allied efforts. A more comprehensive common framework to assess, prioritize, enable, and accelerate the development and deployment of EDTs is needed to ensure NATO achieves greater progress in the development and fielding of these technologies to strengthen deterrence and defense. Without this, the Alliance may end up fighting the last war rather than the next one.
As mentioned above, NATO, the EU, and their member nations have made progress in identifying common defense tech priorities. However, to further refine these into a more focused set of specific shared goals and provide compelling data to help enforce these priorities across allied nations, this study has developed an EDT Innovation Matrix. The EDT Innovation Matrix is a five-factor graph to assign a holistic prioritization level to individual EDTs. The Matrix assesses technologies based on five key factors: the time it will take to develop the technology, the immediate need for the technology, an educated estimation of cost, presumed policy challenges to development and implementation, and the transformative potential of each EDT. This approach ensures that EDTs are examined through a similar lens and works to prevent recency bias.
This is a tool that can be used by NATO and the EU to identify and rank priority technologies for the institutions, but nations can also use it to determine where their national priorities converge and diverge with multinational focus areas. The Matrix allows for concrete quantitative analysis of EDTs, which can help institutions and nations align perspectives and build consensus around tech priorities. This framework can also help nascent bodies such as the NATO Innovation Fund and DIANA chart their strategic direction and develop project selection criteria.
Importantly, the EDT Innovation Matrix is not just a static ranking of current technologies. Rather, it provides a replicable framework for allies to assess and balance future tech priorities. For example, as new technology suites – particularly those centered around AI – come online, the Matrix can act as a basic framework to conceptualize future strategies and prioritization across the Alliance. The EDT Innovation Matrix can help ensure that the Alliance’s EDT strategy and priorities remain relevant as the threat environment and technological landscape rapidly evolves.
The EDT Innovation Matrix below uses five variables, coded qualitatively and quantitatively by way of a cross-sectional literature review of the following:
To demonstrate the utility of the framework and exemplify the EDT Innovation Matrix, this study selected and ranked five technologies that can give the Alliance the most strategic ROI and elevate its competitive edge.
This assessment was scoped to focus on EDTs that are principally dual use in nature, in line with NATO’s current list of priorities. Least understood and most contested within the Alliance (with respect to how they can be deployed), dual-use technologies bring more value to governments due to their diverse applications and serve as key enablers for the Alliance across a wide spectrum of military and civilian capabilities. They are also easier to fund, from both government and private-sector sources, given their broader commercial potential. While this study focuses on the military applications of these technologies, these attributes make dual-use technologies particularly attractive and practical as priorities for the Alliance. This assessment also focused on technologies with near-term military application timelines (i.e., currently deployed or will likely be deployed within five years), which are most relevant for immediate NATO planning and require urgent attention.
Within these parameters, this study identified the following five technologies as key priorities for the Alliance: space-enabled capabilities, unmanned systems, hypersonics, edge computing, and cognitive influence capabilities. ⁵⁴ These were selected due to their relative need, feasibility (based on required time, cost, and policy barriers), and potential for transformative impact on the Alliance’s overall capability vis-à-vis Russia and China in future warfare. ⁵⁵
Space-enabled capabilities such as geospatial intelligence, GPS, and satellite communications, provide better, more real-time intelligence to decision-makers. They also enable military headquarters to effectively manage battlespaces and constitute the core capability connecting platforms and warfighters across the globe. ⁵⁶ In recent years, the use of these capabilities has proliferated across the defense, commercial, and civil arenas. In turn, NATO’s dependence on these capabilities, both as enablers and core technologies, has drastically increased.
The establishment of space forces across adversaries and allies over the last decade is a key contributor to this, along with the growing democratization of these technologies, which were previously only under the purview of major state actors. More players mean more risks for the Alliance, which has become accustomed to having the upper hand in the space domain. Exacerbating the challenge is the growing ability of commercial tools to replicate national defense capabilities – a phenomenon that will only accelerate with the broader space market predicted to exceed $1 trillion by 2038. ⁵⁷ At the same time, Russia and China are leading new efforts to develop and employ space capabilities apart from NATO-driven international space arrangements, ⁵⁸ and have demonstrated their ability to manipulate commercial activities for their own geopolitical gain. ⁵⁹
Russia and China have different capabilities and legacy technologies, but similar aims. First, they have recognized space as a warfighting domain longer than the US or NATO and, thus, believe space is critical to their own future operations and broader great power competition. ⁶⁰ Beyond that, both have also learned that while the US and NATO were able to dominate key warfighting domains during the West’s global war on terror, the vast majority of their capabilities rely on access and freedom to act in space. Russia and China would like to dominate space, but in the near term, their aims are focused on the ability to mitigate the West’s positioning. Further, if tensions escalate, they want to be able to readily disrupt tools, such as GPS and satellite communications, which NATO relies on to pursue operations. US forces have detected evidence of Russia using local GPS jamming during the full-scale invasion of Ukraine in 2022. ⁶¹ It is yet to affect their operations but it is unknown what the effects have been on local forces on the ground. ^{62 63}
Unmanned systems (UxS) have traditionally been key sources of intelligence, surveillance, and reconnaissance (ISR) capabilities, while more recently providing the ability to directly strike targets. They provide this capability at an order of magnitude with lower cost than manned aerial assets while minimizing risk to pilots’ lives. ⁶⁴ This makes them attractive in terms of feasibility and impact, especially to Russia and China which rely on these asymmetric, low-cost tools to upend NATO and US high-end capabilities. Their use is increasingly transformative, as they have had a significant force-multiplying effect when paired with other assets. This was evidenced in the recent Nagorno-Karabakh conflict between Armenia and Azerbaijan, which showcased new applications of drones with which Allies are still grappling. ⁶⁵
Unmanned aerial vehicle’s (UAVs) have played a significant role in Ukraine’s fight against Russia, with Ukrainian forces aiming to build an “army of drones” that will allow for constant monitoring of the frontline. This is coupled with the thousands of commercial drones that are used for real-time battlefield intelligence. ⁶⁶ UxS, particularly unmanned aerial systems (UAS), also have several valuable civil and commercial uses, including delivering packages and supplies ⁶⁷ and transporting critical medical aid, ⁶⁸ which can support allied civilians and militaries. This adds to their appeal as low-cost, low-risk, high-reward capabilities.
The need for NATO to harness these capabilities is rising, especially as UxS continue to evolve and gain new and enhanced features as individual platforms, swarms, and augmentation to existing operations. Beyond UAS, unmanned surface vehicles, unmanned underwater vehicles, and unmanned ground vehicles are coming online across the world with relatively short timelines. ⁶⁹ Many of these also have commercial uses similar to UAS and will benefit from significant revenue growth from the private sector, from retail customers to power companies. While some doctrinal and regulatory issues have yet to be addressed, there are already some policy initiatives underway for UxS, which can facilitate quicker adoption. As these capabilities continue to shape the competitive space, whoever harnesses them quickest and most effectively will have an important advantage, especially on the side of counter-UxS.
Hypersonics are game-changing due to their ability to impact decision-making and mitigate adversaries’ capability advantages. At their core, hypersonic weapons are high-speed weapons that allow for a combination of greater maneuverability, range, survivability, and transformative responses. ⁷⁰ As they mature, these weapons will be able to render even current state-of-the-art defense systems largely ineffective. Hypersonics have the potential to shift the global balance of power and transform the existing capability gap between NATO and near-peer competitors, as well as potential emerging powers. Furthermore, hypersonic propulsion systems developed by the military could be adapted to meet civil and commercial needs for space capabilities or even commercial transport. ⁷¹ This increases their overall strategic value.
The forthcoming generation of hypersonic weapons will drastically shorten decision and reaction times at both tactical and strategic levels. Compared to traditional intercontinental ballistic missiles and cruise missiles, hypersonics combine speed exceeding that of intercontinental ballistic missiles, along with the high-end maneuverability of a cruise missile. If used by adversaries, these two factors can mitigate the US’s and NATO’s capability advantage in areas such as its blue-water navy, overseas bases, and associated power projection.
Because next-generation hypersonics do not need to travel a straight line to their targets, they are harder to defeat once airborne. They exacerbate the risk or increase the likelihood of success of high-impact events, particularly decapitation strikes, as their trajectory – unlike ballistic trajectories – cannot be predicted. There is an urgent need for developing defense capabilities for hypersonic weapons. Further, it is difficult to determine who fired them, which also makes it challenging to deter or retaliate against a hypersonic attack. ⁷¹ This increases the risk of miscalculation and unintended escalation, underscoring the need for NATO to focus on these capabilities.
Edge computing brings mobile computing and data processing solutions to the network’s edge, where the users and devices are located in the field. Because this data does not have to travel back to a center to be processed, it enables faster analysis and more timely and relevant insights. ⁷² Edge computing has high-impact effects on issues spanning homeland security, civil emergency response, crisis management, and multi-domain military operations which make it extremely valuable to the Alliance’s wide range of activities. In the latter case, it has enormous benefits for militaries, supporting more seamless joint command and control (C2), connecting sensors to shooters, enhancing situational awareness, providing real-time data to personnel in the field, and enabling rapid response. ⁷³
Edge computing also provides a foundation to empower lower-level commanders to make decisions in time-sensitive situations, particularly where decision speed is critical. As reach back cannot be guaranteed in today’s contested environment, flattening the “sensor to shooter” architecture and pushing data forward is a game changer. The results of this will have a profound impact on the way NATO fights and reacts to conflict and pre-conflict scenarios. These capabilities also provide the foundation for multi-domain operations, which is the future framework for US and NATO operations. ⁷³
Edge computing systems are quickly becoming more available at lower costs, in part to keep up with commercial and industrial needs. ⁷⁴ They are in turn becoming more integral to military activities, underscoring the need for the Alliance to keep up. Disagreements over data-sharing, privacy, and intellectual property regulation will inhibit the rapid adoption of edge technologies at the transatlantic level. However, the need may outpace the policy challenges. The ability to generate insights and rapid response at both the tactical and strategic levels is critical to winning the next fight. ⁷⁵ Edge computing could be a key enabling capability for NATO’s intent to strengthen deterrence and defense, especially forward presence in the East, announced at the Madrid Summit. ⁷⁶ Without the capabilities edge computing brings, NATO would be left operating on a Cold War hub-and-spoke model that cannot keep up with the changing character of warfare.
Cognitive influence capabilities combine information warfare and cyber tools to target a population to alter how they think, and consequently, how they act. ⁷⁷ The ability to manipulate foreign societies from within and quietly infiltrate their leaders’ decision-making processes can determine the result of hostilities before they ever conventionally start. In today’s hyper-connected world of individual devices, apps, and myriad media sources, it has never been easier to influence public opinion, elections, information flows, and even behavior inside adversary countries. ⁷⁸ Already, Russia and China have actively used cyber espionage, data hack-and-release tactics, disinformation, psychological operations, and similar tools against the transatlantic community, creating pervasive threats that fall below NATO’s traditional threshold of armed conflict and impede swift response. ⁷⁹ These methods provide a low-cost, relatively quick option with high impact. For example, they allow Russia and China to destabilize NATO from within without ever firing a shot. This is the Alliance’s greatest shortfall, and a key vulnerability affecting strategic competition with Russia and China. ⁷⁹
As adversaries continue to push the limits of these capabilities, NATO must develop cognitive influence superiority. In the Cold War, NATO maintained a robust set of cognitive influence capabilities, which it subsequently lost as great power competition subsided. ⁸⁰ As technology has advanced in the cyber and information domains, the Alliance must urgently relearn how to take back the initiative and rebuild an innovative toolbox to shape its adversaries’ mindsets. The policy challenge for Allies will be to develop and deploy these tools in a way that is consistent with NATO’s shared values and principles such as human rights and the rule of law. ⁸¹ As has been clearly demonstrated in Russia’s recent full-scale invasion of Ukraine, the ability to win the war of hearts and minds will be at the center of any future conflict.
The five selected technologies were assessed within the stated parameters. A demonstration of the replicable EDT Innovation Matrix may be seen below. Both visuals provide alternative ways in which the assessment can be presented.
For a chosen EDT, an assessment is made using the five variables identified. 1) Time: Low, Medium, High; 2) Need: Met, Unmet, Future; 3) Impact: Core, Adjacent, Transformational; 4) Cost: Limited, Medium, Significant; 5) Policy Challenge: Limited, Medium, Significant. The five colors represent the level of challenge regarding that specific variable. The colors can be seen as a visual representation of a scale of 1-5 (1= dark green and 5 = red).
It must be noted that the color is a distinct assessment from the word. For example, although unmanned systems (UAS) meet a current need, it is coded as red because there are significant gaps within UAS such as the lack of effective counter-UAS systems and operating ability in denied environments.
In the chart format each of the five variables of the EDT Innovation Matrix are represented visually. 1) Time and 2) Need are shown on the axes, and 3) Impact is on the background of the chart. The 4) Cost is represented by the size of the circle and 5) Policy Challenges is represented by the color of the circle.
A key technology excluded from this assessment is machine learning (ML) as a subset of artificial intelligence (AI). AI and ML capabilities hold transformative potential for expanding knowledge, increasing prosperity, enhancing security, and enriching the human experience. This technology will be a source of enormous power for countries that harness them, fueling competition between governments and companies racing to employ them for strategic ambitions. ⁸² However, as governments have placed an increasing emphasis on the development and adoption of AI, including for security and defense, a vast new body of literature has emerged on these technologies. ⁸³
Policy discussions on the security applications of AI and ML have become commonplace across Washington, DC; Brussels; and Allied capitals, and national strategies for AI have already been released. ⁸⁴ As a shared understanding of these issues grows, the research team decided not to focus on AI/ML as a technological priority in isolation, but rather as an enabling technology present across virtually all emerging technology suites, including the five outlined above.
Other key technologies excluded from this particular assessment that could be prioritized in the slightly longer term include quantum-enabled technologies, synthetic training environments, CRISPR-enabled biological warfare, strategically effective cyberattacks, civil information integration (e.g. smartphones used for targeting in Ukraine), and directed energy, among others.
Perhaps even more important than identifying common transatlantic technological priorities is the need to develop a shared policy framework to act upon these priorities. NATO, the EU, individual nations, and industry leaders all have unique roles to play in helping the Alliance more effectively harness emerging technologies for its own defense, deterrence, and strategic advantages. However, one critical element is missing: a shared transatlantic policy framework to help align actions across all these stakeholders. Such a policy framework would provide a common lens through which NATO, the EU, and their member nations can conceive, discuss, coordinate, and implement all efforts to enhance the Alliance’s technological edge. This blueprint would serve as a basis for stronger cooperation with industry practitioners – who are the key drivers of innovation – as well as stronger coordination with other like-minded nations outside the Euro-Atlantic area, including those in the Indo-Pacific. Such coordination will be critical for competing against China’s technological rise.
As with all policy frameworks, they are only as valuable as their implementation. The authors recommend developing an accompanying roadmap with key performance indicators (KPIs) to help measure the progress and implementation of the recommendations. An initial idea is provided in Appendix 1.
The following core pillars should serve as the foundation for this transatlantic policy framework for defense tech cooperation:
While most Euro-Atlantic governments and institutions acknowledge the importance of investing in defense tech, differing views on how to approach Russia and China drive disparate budgetary priorities, policy development, and levels of political will to act. To harmonize collective efforts, Euro-Atlantic allies and partners need a deeper, shared threat assessment of the tech competition. This would also provide a basis to cooperate with like-minded partners outside NATO and the EU. To be more proactive, allies and partners must shift their mindset away from examining tech threats and toward exploring tech opportunities. The Alliance cannot afford to be reactive, waiting to see how Russia, China, or other actors may weaponize emerging technologies. Instead, it must shape the competition and anticipate future needs to stay ahead of the curve.
Recommendations:
Many Euro-Atlantic nations and institutions have their own lists of priority technologies and nascent tech strategies, some of which overlap with each other. However, many of these plans are too focused on the technologies themselves (i.e., investing in AI because it is important), as opposed to the desired effect (i.e., what exactly the AI will be used for). If transatlantic entities channel their efforts into solving a few specific collective problems with tech, they could better align R&D funds and maximize results. Tying innovation projects to specific use cases and direct paths to production contracts would facilitate faster adoption of technology. This requires a shift in focus from individual technologies to a more holistic focus on desired capabilities and outcomes. While an over-emphasis on use cases can constrain innovation in the private sector, this approach can be effective for multilateral cooperation.
Recommendations:
Despite the stated desire to increase transatlantic tech cooperation, many governments have failed to sufficiently adjust the regulatory environment to better facilitate such collaboration. Major legislative barriers such as International Traffic in Arms Regulations (ITAR), which governs export controls and tech transfer, as well as complex, slow-moving contracting processes hinder innovation. They impede multinational collaboration, complicate intellectual property (IP) management, and make it costly and time-intensive for the industry to do business with governments. The current regulatory environment not only reflects a general distrust of industry, it also underscores the ongoing competition for economic interests among transatlantic nations over industrial base issues. This is particularly the case with private businesses that seek a profit to advance the interests of the nation, also known as “national champions,” many of which are still owned in part by various European governments. A greater sense of urgency among nations to put the long-term collective good of the alliance above short-term economic gains would help find ways to relax or work around legislative barriers that impede allied interests in the tech competition with Russia and China.
Another regulatory priority is the need to establish shared transatlantic principles to govern how defense and dual-use tech is deployed, in order to shape the rules of the road before Russia and China do so. A lack of shared transatlantic principles to govern EDTs will have a direct impact on collaborative innovation, interoperability, and the ability to create a unified value proposition for a democratic technology model to compete with the authoritarian model of Russia and China.
Recommendations:
Current government procurement and innovation cycles tend to favor large traditional defense companies, or “primes,” which have the knowledge, experience, and capital to navigate lengthy and complex contracting procedures. This makes it difficult for new players, such as start-ups driving radical innovation, to break in. Bureaucracies are often naturally risk-averse and hesitant to work with nontraditional players which can be more volatile. Yet there is a longer-term risk in not exploring these options, specifically that without them, Western governments could be left behind. To stimulate real innovation, governments must make big bets, embrace failure as an option, and commit to engaging these partners, especially those housing dual-use technologies outside of the defense realm. Pushing start-ups to be sub-contractors under primes does not always create mutually beneficial arrangements, therefore governments should also provide more agile contract models for nontraditional companies.
Recommendations:
The private sector spends five times as much on R&D as the public sector and thus has outpaced it in driving innovation priorities. Transatlantic governments and institutions often struggle to understand what solutions exist on the market to solve their most pressing problems – especially when those solutions exist outside the defense realm. Part of the issue stems from the lack of key technical talent inside governments and institutions who understand their organizations’ needs and have the time, network, and expertise to scrape technology from the field and share that information among NATO Allies. While it is difficult to compete with private-sector salaries, NATO, the EU, and governments must better recruit, retain, and fund these roles.
Recommendations:
Another pressing challenge is encouraging governments to invest in testing and evaluation procedures and facilities that enable companies to better demonstrate the value of their technology, allowing them to adapt to institutional needs, help operators become comfortable with new systems, and ultimately lead to easier integration. NATO, the EU, and their governments should create more incentives, pathways, and resources to help industry get to, and through, the prototyping and testing phase.
Recommendations:
Data-sharing is an integral aspect of the Alliance’s ability to compete with China and Russia from tech development all the way through to deployment. Allies and partners should be able to share sensitive technologies, data, and intellectual property that can enhance their collective advantage. Major capabilities, such as joint all domain command and control (JADC2), and the technologies that enable them, such as AI algorithms, hinge on data moving across stakeholders and networks. Yet, this remains challenging. In part, this is due to technical issues, regulatory constraints, classification, and bureaucratic tensions that prevent sharing. But it is also due to a lack of trust among governments that shared data or IP will be protected and used for mutually beneficial purposes. Additionally, in light of the increasing reliance on dual-use technologies, more work must also be done to understand the impact of data-focused legislation, such as the EU’s General Data Protection Regulation (GDPR), Digital Services Act (DSA), and Digital Markets Act (DMA), on NATO’s ability to leverage technology for military purposes.
Recommendations:
Interoperability is critical to ensure allies and partner technologies, capabilities, and forces can work together. Several useful interoperability initiatives and standards exist, especially within NATO, but they are sometimes difficult to implement, evaluate, and enforce. Transatlantic institutions should explore how to empower existing mechanisms and monitoring committees to assist with enforcement in multinational contexts. Going forward, interoperability must be integrated from ideation to development and eventual deployment, rather than as an afterthought.
Recommendations:
The growing focus on emerging tech across the transatlantic community has led to the proliferation of innovation funds and bodies, but many of them lack the right authorities, mandates, resources, structure, or talent. Allies and partners have diverging views on how these frameworks should be used. There is a risk of fragmented efforts, duplication, and innovation theater. Different funding instruments across NATO, EU, and member nations should be brought together to better leverage joint scaling opportunities. Innovation and investment cycles across governments should be aligned and accelerated. Current entities should be properly empowered and staffed.
Recommendations:
Although the military technological capability gap enjoyed by the US and other NATO Allies over their adversaries has substantially shrunk in recent years, it is not completely closed. To elevate its edge in today’s era of intensifying strategic competition, the transatlantic alliance must work together to increase its ability to drive the development, deployment, operational and — most importantly — conceptual integration of emerging technologies.
To accomplish this goal, the Alliance must focus most urgently on transformational, dual-use technologies with near-term application timelines. This study suggests five key technologies for the Alliance to prioritize that can provide the most return on investment. These include space-enabled capabilities, unmanned systems, hypersonics, edge computing, and cognitive influence capabilities – the first three of which align with NATO’s current nine priority areas. Successful pursuit and exploitation of these technologies will help define the role of the transatlantic alliance for the generation to come. Notably, this study also offered a replicable mechanism to assess new technologies as they emerge, which will help the Alliance adapt its priorities in the ever-evolving tech landscape.
NATO, the EU, their nations, and private industry all have unique roles to play in helping the transatlantic community compete in defense technologies. To help these stakeholders work together, this study provided one critical element missing from current debates: a shared policy framework for defense tech cooperation. This strategic approach is built upon nine core policy pillars: 1) forge a common assessment of the threat competition; 2) facilitate faster adoption of tech; 3) improve the regulatory environment; 4) incorporate nontraditional partners to inspire radical innovation; 5) continuously scout for tech solutions and talent; 6) increase testing and evaluation; 7) enhance data-sharing among Allies; 8) improve interoperability and standardization; and 9) connect and better align tech efforts.
Importantly, this study offered fifty distinct recommendations under each of these pillars to help policymakers implement the proposed framework. This is accompanied by a working concept for one-year, three-year, and five-year KPIs in the following appendix to help measure progress over time.
Together, these three elements – a repeatable mechanism for assessing and prioritizing key technologies across the alliance; a policy framework to align and coordinate actions across NATO, the EU, nations, and industry; and short-term targeted recommendations for policymakers to implement the policy framework – comprise a compelling transatlantic strategic concept for competing in defense technologies. The time to think and act boldly is now. Policymakers throughout the transatlantic community should urgently adopt this framework and help elevate the Alliance’s strategic edge by winning the twenty-first century race for technological innovation.
The following table on KPIs is an early draft of what the authors view as a useful and necessary tool for planning and measuring success within EDTs. At present few government organizations use available best practices, primarily from the tech sector, to measure progress and success in advance of developing and implementing new strategies and/or policies. While the KPIs provided are largely qualitative in nature and require further refinement, which is planned in a potential future piece, they provide a good starting point for how success in developing and deploying EDTs can be measured, which is critical in multi-stakeholder, international environments.
To encourage the policy community to move the dial forward in each of the priority technology areas, the research team developed series of working draft KPIs under each policy pillar to help measure progress and implementation of the recommendations.
KPIs are broken out into one-year, three-year, and five-year markers. In the most optimal situation, each ally would declare a specific “focus area,” choosing a singular pillar or group of recommendations and working to facilitate implementation. However, NATO could utilize these indicators as a roadmap to assess defense tech progress and overall Allied cohesion on a larger level.
Each pillar is found in the tables below, subdivided into its individual recommendations, and populated with a one-year, three-year, and five-year KPI for each.
*The list below is not exhaustive of all individuals consulted for this project, as some preferred to remain anonymous. The ideas expressed in this report do not necessarily reflect the views of any individual listed below.
Project Advisors
EU
NATO
Experts & Industry
We are extremely grateful for the advice and expertise of Lauren Speranza, former Director of the Transatlantic Defense and Security program at CEPA, and MG (Ret.) Gordon B. “Skip” Davis, CEPA Senior Fellow, who served as a core senior advisor on this project. We are also thankful to Col (Ret.) Brian Michelson, CEPA Senior Fellow, and Joel Hickman, Deputy Director of the Transatlantic Defense and Security program at CEPA, who served as key project contributors. We owe debts of gratitude to the many senior officials, experts, and industry practitioners who shared their time and insights with us through interviews, consultations, and workshops hosted by CEPA. We also thank Krista Viksnins, CEPA Program Assistant, and Gabrielle Moran, former CEPA Program Assistant, for their efforts in coordinating this project.
James G. Foggo III is a Distinguished Fellow with the Center for European Policy Analysis. Foggo is a 1981 graduate of the US Naval Academy. He is also an Olmsted Scholar and Moreau Scholar, earning a Master of Public Administration at Harvard University and a Diplome d’Etudes Approfondies in Defense and Strategic Studies from the University of Strasbourg, France. He commanded the attack submarine, USS Oklahoma City (SSN 723) in 1998, which was awarded the Submarine Squadron (SUBRON) 8 Battle Efficiency award and the Commander Fleet Forces Command Admiral Arleigh Burke Fleet Trophy for being the most improved ship in the Atlantic Fleet. Foggo served as Commodore of SUBRON-6 in 2007.
Over the last decade in Naples, Italy, he served in multiple major commands as Commander, Naval Forces Europe/Africa; Commander Allied Joint Force Command, Naples; Commander, US Sixth Fleet; Commander, Submarine Group 8; and Commander, Submarines, Allied Naval Forces South. During this period, he also served as the Operations Officer (J-3) for Joint Task Force Odyssey Dawn (Libya). Additionally, Foggo was a NATO Task Force commander in Joint Task Force Unified Protector (Libya). In 2018, he commanded Exercise Trident Juncture (Arctic Circle), the largest NATO exercise since the Cold War with over 50,000 personnel.
Ashore, he has served in a variety of assignments, most notably as Executive Assistant to the Director of Naval Nuclear Propulsion (NAVSEA 08); Executive Assistant to the Chairman of the Joint Chiefs of Staff; Executive Officer to the Supreme Allied Commander Europe (SACEUR) and Commander, European Command (EUCOM); and Director, Navy Staff.
Foggo’s awards include the Defense Distinguished Service Medal, Distinguished Service Medal, Defense Superior Service Medal, Legion of Merit, and NATO Meritorious Service Medal. In addition, he was awarded the 1995 Adm. Charles A. Lockwood Award for Submarine Professional Excellence and the State of Oklahoma Distinguished Service award by the adjutant general. In 2006, he was awarded the Chevalier de l’Ordre National de Merité and in 2017 he was awarded the Legion d’Honneur by the French Government. In 2020, he was awarded the Canadian Meritorious Service Cross, Commander of the Order of Merit of Italy, and Commander of the Cross of Saint George from Portugal. In 2021, he was awarded the Grand Cross of Naval Merit of Spain. Foggo is also a member of the Council on Foreign Relations, the American Academy of Diplomacy, the Explorer’s Club of New York, and has served on Advisory Boards to the Naval Submarine League, Olmsted Foundation Board, and US Naval Institute Board. He is currently an active member of the Marine Corps University Editorial Board in Quantico, VA.
Nicholas Nelson is the Senior Fellow for Emerging Tech and Policy with the Transatlantic Defense and Security Program at the Center for European Policy Analysis (CEPA). He is an experienced leader in aerospace and defense (A&D), working at the nexus of innovation and national security. In addition to his work at CEPA, Nelson is the Senior Technology Advisor at the Georgia Institute of Technology, focused on emerging defense and dual-use technologies. He also advises a range of venture-backed startups. Previously, he was the Director of Strategic Development at a seven-billion-dollar A&D and technology company, leading strategy, mergers and acquisitions, and corporate venture capital initiatives. Prior to this, Nelson worked in management consulting and technology scouting in Europe and North America, as well as civilian roles with the U.S. Department of Defense.
His research and writing are focused on emerging defense technology, hypersonics, unmanned systems, and great power competition. His analysis and writing have been featured in Defense News, National Defense Magazine, DefenceiQ, and SpaceNews. Nelson is an elected Fellow of the Royal Aeronautical Society and Royal Society for the Encouragement of Arts, Manufactures, and Commerce in London.
Joanna van der Merwe is a Non-resident Fellow with the Defense Tech Initiative at the Center for European Policy Analysis (CEPA). Joanna holds an MA in International Relations and Global Conflict in the Modern Era and a BA in International Studies from Leiden University. Joanna is currently a Senior Policy Advisor at the Centre for Innovation at Leiden University and a Fellow at the International Strategy Forum hosted by Schmidt Futures and the European Council on Foreign Relations. She has conducted her research in collaboration with the Land Warfare Centre of the Netherlands Ministry of Defence, focusing on artificial intelligence (AI) and the future of combat. This research built on her previous experience at the Netherlands Army looking at big data on the future battlefield. She has also worked on early warning systems for mass atrocities at the Signal Program on Human Security and Technology at the Harvard Humanitarian Initiative. She also continues to advise and speak on data and AI in contexts such as policy-making and the future of warfare and defense.
Nico Luzum is a consultant with Deloitte Consulting Government and Public Sector focused on emerging technology. Prior to this, he served as a Defense Tech Consultant on the Transatlantic Defense and Security (TDS) team at the Center for European Policy Analysis. His background and expertise lie at the intersection of innovation, emerging and disruptive technology, and international security. Luzum is an alumnus of the Georgia Institute of Technology in Atlanta, Georgia, where he graduated Magna Cum Laude with a Bachelor of Science in International Affairs and Modern Languages with a concentration in Chinese. He also earned a Master of Science in International Security. In addition to his work at CEPA, Luzum led two research teams in conjunction with the NATO Allied Command Transformation (ACT) Hub.

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