By the year 2030, a bold plan unfolds within the National Center for Physics and Mathematics’ scientific program, aimed at reshaping Russian research infrastructure. The vision calls for a modern academic campus, a dedicated science institute capable of housing around two thousand specialists, and three mega science facilities that push the envelope of current technical performance. These ambitions, shared by Alexander Sergeev, Academician of the Russian Academy of Sciences and scientific director of NTsFM, underscore a national commitment to world-class science and to elevating Russia’s role on the global stage. The plan envisions a campus that acts as a hub for collaboration, innovation, and advanced training, linking researchers, engineers, and students in a dynamic ecosystem that mirrors leading international centers of physics and mathematics. It also includes state-of-the-art laboratories and integrated facilities designed to support long-term experimental and theoretical work, fostering breakthroughs across multiple disciplines. This strategic investment is positioned as a cornerstone for sustaining scientific leadership and economic competitiveness in the coming decade. (Citation: NTsFM leadership and national science program communications)
With continuous collaboration between RFNC-VNIIEF and fifty-four other scientific and educational institutions nationwide, the early, rapid-launch phase of the NCFM program has reached a milestone. The plan for 2023–2025 focuses on expanding the NTsFM site in the open-zone area of Bolshoy Sarov by creating new laboratories capable of supporting large-scale, cross-disciplinary research. The leadership emphasizes that, by 2030, the project will deliver three mega facilities, a science institute employing around two thousand people, and a fully operational academic campus designed to house and nurture a community of ten thousand researchers and staff. This expansion is framed as a long-term commitment to enabling experimental programs, computing resources, and collaborative networks that can accelerate discoveries in fundamental physics and mathematics. (Citation: RFNC-VNIIEF and national collaboration statements)
Readers gain insight into the ambitious agenda because the program also envisions practical advances such as methods for matter and antimatter studies in space-like conditions, the construction of collider-like facilities to probe elusive signals of dark matter, and the controlled generation of high-energy phenomena in laboratory environments. These tasks illustrate the breadth of scientific challenges being pursued—from understanding fundamental forces to exploring cosmological mysteries. The broader objective is to develop capabilities that not only advance theoretical knowledge but also enable experimental techniques with wide-ranging applications in energy, technology, and materials science. Further details and progress updates are discussed in the science program coverage and institutional briefings. (Citation: program overviews and institutional announcements)