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Advanced magnetic materials fusion research at VCU College of Engineering receives $500K grant from Virginia Clean Energy Innovation Bank

Feb 4, 2026

2 min

Radhika Barua, Ph.D.

Supporting fusion energy system development in the state, the Virginia Commonwealth University (VCU) College of Engineering will acquire an ultrasonic metal-powder atomizer to advance critical research in magnetic materials needed for compact fusion reactors. Made possible by a $500,000 grant from the Virginia Clean Energy Innovation Bank (VCEIB), the funds support VCU Engineering’s Advanced Magnetic Materials Processing Laboratory (AM2P), enabling VCU Engineering to establish Virginia’s first in-state capability for producing custom, high-purity metal powders tailored for next-generation fusion reactor components.


“Clean-energy innovations from fusion to grid-scale technologies demand materials that can operate under extreme conditions while remaining manufacturable at scale,” said Radhika Barua, Ph.D., assistant professor in the Department of Mechanical & Nuclear Engineering and director of AM2P. “This project will be transformative as we can now design advanced alloy compositions, produce them in-house, and immediately integrate them into additively manufactured components—dramatically accelerating the innovation cycle.”


This project positions Virginia to capture a share of the rapidly expanding fusion materials and advanced manufacturing market, projected to surpass $8 billion annually by 2035. Also, this investment is expected to unlock more than $4 million in additional federally competitive research funding over the next four years.


“This is a smart, high-impact investment in Virginia’s energy future,” said Glenn Davis, director of the Virginia Department of Energy. “By establishing in-state powder atomization and advanced materials capability, we’re positioned to become a critical node in the emerging fusion supply chain while strengthening our defense and clean-energy industrial base.”


This comes on the heels of last year’s announcement that Commonwealth Fusion Systems will make a multibillion-dollar investment to build the world’s first grid-scale commercial fusion power plant in Chesterfield County.


The AM2P Lab has emerged as one of the few academic research centers in the nation with deep expertise in additively manufactured permanent magnets, soft magnetic alloys and magnetocaloric materials.


“This equipment and research will not only support fusion activities but also open doors for collaborative activities with multiple federal agencies including the Army Research Laboratory, the Air Force Office of Scientific Research and the Office of Naval Research,” said Arvind Agarwal, Ph.D., professor and chair of the Department of Mechanical & Nuclear Engineering.


“This grant accelerates Virginia’s leadership in advanced nuclear and fusion manufacturing while strengthening workforce readiness,” said Julianne Szyper, deputy director of the Virginia Department of Energy. “By connecting Virginia’s academic talent with industry and national lab partners, we’re creating an ecosystem that drives innovation, supports high-quality careers and positions the Commonwealth as a competitive hub for clean-energy technologies like fusion.”

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Radhika Barua, Ph.D.

Radhika Barua, Ph.D.

Assistant Professor, Department of Mechanical and Nuclear Engineering

Dr. Barua specializes in developing multifunctional magnetic materials systems for diverse applications in the power & energy sector.

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VCU College of Engineering Dean Azim Eskandarian, D.Sc., named Fellow of The Society of Automotive Engineers International featured image

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VCU College of Engineering Dean Azim Eskandarian, D.Sc., named Fellow of The Society of Automotive Engineers International

Recently named a Fellow of the Society of Automotive Engineers (SAE) International, Azim Eskandarian, D.Sc., the Alice T. and William H. Goodwin Jr. Dean of the Virginia Commonwealth University (VCU) College of Engineering, received one of the organization’s highest honors. The designation recognizes individuals who have made extraordinary and sustained impacts on the mobility industry through technical excellence, leadership, innovation and dedicated service to the profession and to SAE International. “SAE Fellows – whose leadership and technical contributions strengthen our organization embody the highest level of professional achievement,” said Carla Bailo, 2026 SAE International president and chair of the board of directors. “Election to SAE Fellow reflects an individual’s lasting influence on mobility engineering and reinforces the standards of excellence that guide SAE’s strategic direction.” Selected through a comprehensive review process led by the SAE International Fellows Committee and approved by the SAE International Board of Directors, SAE Fellows exemplify the organization’s mission to advance mobility knowledge and solutions for the benefit of humanity. “It is a great honor to receive this distinction from an organization that is so essential to the advancement of the automotive industry,” said Eskandarian. “I hope to continue collaborating with engineers, researchers and other professionals who share a vision for the great work we can do to improve the safety and efficiency of transportation.” Numerous scientific and technical contributions to automotive safety, academic programs, workforce development in crashworthiness, collision avoidance, advanced driver assistance systems, intelligent vehicles, and autonomous driving have stemmed from the more than 40 years of work Eskandarian has pioneered. His research on intelligent and autonomous vehicles includes the development of novel methods for driver safety systems. As an academic leader, Eskandarian’s enduring commitment to education, mentorship and service led him to start impactful academic programs at several universities. This includes robotics and autonomous systems programs and new master’s concentrations at the VCU College of Engineering, a graduate academic program in intelligent transportation systems and an undergraduate concentration in transportation engineering at George Washington University, and an automotive engineering concentration at Virginia Tech. Eskandarian is also a Fellow of two other technical societies, the American Society of Mechanical Engineers (ASME) and the Institute of Electrical and Electronics Engineers (IEEE).

VCU College of Engineering receives $600,000 for AI-driven cybersecurity research featured image

2 min

VCU College of Engineering receives $600,000 for AI-driven cybersecurity research

To advance AI-enabled cybersecurity research, the National Science Foundation (NSF) presented Kemal Akkaya, Ph.D., professor and chair of the Department of Computer Science, with a $600,000 grant through the organization’s Cybersecurity Innovation for Cyberinfrastructure program. Akkaya’s three-year project will explore how large language models (LLMs) can automate packet labeling for intrusion detection systems. “From transportation and healthcare to finance, improving the accuracy of machine learning algorithms used to defend the networks that underpin these sectors’ cyberinfrastructure is critical for protecting them from cyberattacks. Strengthening these defenses helps ensure the reliability and security of the essential services people rely on every day,” said Akkaya. Intrusion detection systems monitor network traffic to identify suspicious or malicious activity. These systems rely on machine learning models trained on large volumes of accurately labeled data. Producing those datasets, however, is time intensive and often requires expert cybersecurity knowledge. As digital systems increasingly power transportation, health care, finance and communication, the volume and sophistication of cyber attacks continue to grow. At the same time, artificial intelligence is reshaping how both attackers and defenders operate. Improving how quickly and accurately security systems can be trained is critical to protecting the infrastructure that supports daily life. Akkaya’s project will investigate how generative AI can help address this challenge. The team will fine tune open-source large language models using network data, threat signatures and expert annotations. Model accuracy will be strengthened through retrieval-augmented refinement, ensemble modeling and human-in-the-loop verification. Labeled datasets will be released in stages to support the development and evaluation of cybersecurity models. Using data from AmLight, an international research and education network operated by Florida International University (FIU), the project includes collaboration with researchers from FIU. The award strengthens VCU’s growing leadership in AI-enabled cybersecurity research and provides hands-on research training for graduate students. Resulting datasets from this work will support machine learning education for undergraduate students.

Director Gennady Miloshevsky, Ph.D., shares his vision for the nuclear program at the VCU College of Engineering featured image

5 min

Director Gennady Miloshevsky, Ph.D., shares his vision for the nuclear program at the VCU College of Engineering

Recently named the nuclear program director at the Virginia Commonwealth University (VCU) College of Engineering, Gennady Miloshevsky, Ph.D., associate professor in the Department of Mechanical & Nuclear Engineering, answers some questions about the direction of VCU Engineering’s nuclear program and what he hopes it can accomplish. What are your top priorities for the nuclear program at the VCU College of Engineering? I want to focus on student development, innovative research and our rankings in best program lists, but that is not everything. Strategy is important. We need to align ourselves with the country’s national energy needs. There are many new developments in the energy sector, like small modular reactors or fusion energy systems, and having the right faculty to engage with these advancements is important. Providing students with a well-rounded education and good opportunities for gaining experience benefits the College of Engineering’s public and private sector partners. Nuclear subject matter is complex, so higher education is very important for workforce development. We want to build partnerships, like the one we have with Dominion Energy, that support this goal. A priority for me is continuing to establish relationships with Commonwealth Fusion Systems, which seeks to build and operate the first commercial grid-scale fusion plant in Chesterfield County, Virginia. Our workforce partners will benefit from VCU’s well-trained nuclear engineering graduates joining the workforce. So, aligning our strategy with national energy needs, hiring the right faculty to support our programs and building industry partnerships that benefit our student’s education and career opportunities are important things for VCU Engineering’s nuclear program. Where would you like to see the College of Engineering’s nuclear program 10 years from now? I would like to see growth in the nuclear program. For example, some new graduate courses on topics like nuclear materials or fusion energy. In 2024, I developed a general course for fusion energy, so building out a curriculum that goes more in-depth would be good. When you look at small modular reactors and micro reactors, current energy policy does not allow private companies to build their own. However, as energy demands increase, policy could change to where you see these compact devices installed in places like data centers, for example. A more in-depth curriculum allows VCU Engineering students to step into industry roles that lead growth of the energy industry while also ensuring students are capable of adapting to the changing field and taking advantage of new developments. What sort of cross-disciplinary opportunities are there for the College of Engineering’s nuclear program? Nuclear engineering and nuclear science are very interdisciplinary fields. You have physics that covers the nuclear reaction and the radiation it generates, for example, then chemistry is needed when talking about nuclear fuel cycles and nuclear waste. You also need materials science because good materials capable of withstanding radiation and high temperatures are needed in nuclear fission and fusion energy systems. This science then connects to engineering, building the reactors, the energy distribution systems like a power grid. It is a small sample of the overall work, but you see how mechanical and electrical engineering are key to this part. All these disciplines come together to solve the same problem. One researcher might be figuring out how to confine plasma and make it stable, then another researcher is looking at how plasma can disrupt the containment wall and how to make materials to protect the wall. Within our department, we are making connections between mechanical-focused faculty working on high-temperature ceramics or additive manufacturing techniques and those of us researching nuclear energy systems in order to make joint proposals. We are also collaborating outside VCU. As an example, I am involved with an alliance founded by the Defense Threat Reduction Agency (DTRA) comprised of 17 universities, research labs and military centers. Coordinated through DTRA, we work together on many of the same problems.Through this partnership, my Ph.D. students do summer research rotations with national labs like Lawrence Livermore National Laboratory in California and The Pacific Northwest National Laboratory. We also bring cadets and midshipman into VCU from other institutions, like the DTRA Nuclear Science and Engineering Research Center, United States Military Academy West Point and the Virginia Military Institute, whose students have been part of research experience for undergraduates programs in the summer. How is artificial intelligence impacting the field of nuclear engineering? So, the United States is sponsoring the Genesis Mission, which seeks to transform science innovation through the power of AI. One area of the Genesis Mission is nuclear fission and fusion energy. I see this playing out with the Department of Energy encouraging national labs, universities and industry to work together on applying these AI advancements to solve the research problems of nuclear energy. It is a great opportunity for students, who we can involve in this work to give them real-world experience with topics they will see after graduation. Last semester I taught a course at VCU on the practical applications of AI on nuclear engineering problems. It is not something like ChatGPT or anything like that. What we did is take Google’s TensorFlow platform that is a library of AI models and machine neural networks. Using Python scripting students learn how to apply these AI resources to about 30 problems in mechanical and nuclear engineering. They create scripts, use data sets and run analytics. We have a nuclear reactor simulator and I have some ideas to create AI-based software we can pair with the simulator, then give the software a data set and let it control the operation of the simulator in a safe way. Tell us about your background. What brought you VCU and the Department of Mechanical and Nuclear Engineering? Actually, I am not a mechanical or a nuclear engineer. My background is in physics. I graduated from the Belarusian State University in 1990 and continued to a Ph.D. in physics from the Heat and Mass Transfer Institute of the National Academy of Sciences of Belarus working on topics related to fusion plasmas and nuclear weapon effects. In space, nuclear weapons produce shockwaves and radiation. I computationally model these effects in my research to determine how something like a nuclear warhead detonation in orbit will impact the materials a satellite is made of, for example. My research also crosses over into nuclear fusion, specifically thermodynamic and optical plasma properties, fusion plasma disruptions, melt motion and splashing from plasma facing components. Accelerating Next-Generation Extreme Ultraviolet (EUV) Lithography (ANGEL) is my most recent collaborative project, supported by the Department of Energy’s (DOE) Office of Science, Fusion Energy Sciences. It involves two national laboratories, three universities and a private-sector company focusing on advancement of future micro-electronic chips, EUV photon sources, mitigation of material degradation and plasma chemistry. Prior to joining the VCU College of Engineering I worked at Purdue University at a DOE-funded center investigating nuclear fusion and the effects of plasma on materials. Around 2019 I wanted to develop my own lab, so I came to VCU with startup funds from the Nuclear Regulatory Commission and DTRA. My first priority after joining the VCU College of Engineering was continuing my fusion research, the second was collaborating with an alliance of universities focused on work for DTRA and DOE.

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