Note: The scientific and technological achievements listed here include the predecessor of the College of Nuclear Science and Technology of the University of Science and Technology of China. It mainly conducts research on the design technology of advanced fission nuclear energy systems, including the physical and thermal design technology, nuclear economics and environmental impact research of the third and fourth generation advanced nuclear energy systems (high temperature gas-cooled reactor, fast neutron reactor and molten salt reactor) and accelerator-driven subcritical nuclear energy systems. Using relevant experimental equipment to provide students with teaching experiments and scientific research experiments related to nuclear reactor engineering principles, design and analysis of advanced nuclear reactors and nuclear power systems.
The main research contents include: the third generation nuclear fission reactor design technology, the fourth generation advanced nuclear energy system design, accelerator-driven subcritical nuclear energy system design, radioactive environmental impact analysis, nuclear energy economics research, advanced heat transfer and energy conversion methods research, multi-physical field coupling analysis and experimental verification, the use of EAST superconducting Tokamak experimental platform, participation in ITER experimental package construction and experimental conditions. Advanced plasma physical operation mode research, advanced cladding concept design, high heat flux divertor design, efficient power generation mode design, advanced maintenance strategy design, tritium extraction and control mode design, fusion economics research, radioactive activation product control research, radioactive nuclear waste disposal and power station system research. At the same time, research on advanced nuclear energy system with fusion-fission hybrid reactor as the core is carried out.
The main research contents include: advanced plasma core physical design, advanced cladding concept design, advanced divertor physical and engineering design, advanced energy conversion mode design, fusion reactor power station system maintenance strategy design, auxiliary system design, radioactive activation product disposal strategy research, tritium cycle and control system design research, fusion economics research, fusion-fission hybrid reactor advanced nuclear energy system concept design. Carry out research on key technologies related to cladding, including: experimental research on processing and manufacturing technology of cladding components, design and experimental research on cladding functional materials, experimental research on compatibility of cladding materials, verification of coolant heat-carrying capacity of Qualcomm mass assembly, experimental research on magnetohydrodynamic effect, research on service performance of fusion reactor materials, experimental research on interaction between cladding ferromagnetic materials and plasma, research on post-irradiation inspection technology and development of key unique instruments and equipment.
The main research contents include: experimental research on the processing and manufacturing of cladding components, experimental research on the compatibility between proliferators and structural materials, experimental research on the safety of coolant and proliferators, experimental research on magnetohydrodynamic effect, numerical simulation and experimental research on heat transfer in multi-flow fields, design of high heat flux components, research on the interaction mechanism between ferromagnets and plasma, and scientific research on the properties, preparation technology and welding technology of various nuclear materials. Carry out experimental research on various thermoelectric physical properties, mechanical properties (tensile properties, impact properties, fatigue and creep properties) and irradiation (damage and activation), develop nuclear materials with independent intellectual property rights, and provide data support for fusion engineering technology research and design optimization.
The main research contents are: material preparation and welding technology, experimental research on thermal and mechanical properties of materials, experimental research on radiation properties of materials, research and teaching experiments on neutron physics and nuclear safety related theories, research on methods and procedures related to reactors and other nuclear devices, nuclear safety concept and safety culture construction.
The main research contents include: advanced neutron modeling, calculation and analysis methods, advanced reliability/safety methods, advanced neutron analysis software, and multi-functional and multi-physical effects. The research and development of nuclear database takes medical physics related to tumor radiotherapy as the core, taking into account nuclear medicine and medical imaging technology, solving key physical and technical problems related to radiotherapy by using nuclear physics, mathematics, biology and computer science, and developing related software and hardware systems.
The main research contents are as follows: (1) making a radiotherapy plan for tumor; (2) CT simulation positioning hood/vacuum pad/laser lamp positioning system High-precision dose measurement verification of simulated human model High-precision dose measurement verification of shot field blocking lead making multi-leaf grating control advanced image-guided intensity modulated radiotherapy related software and hardware system research and development advanced dose-guided intensity modulated radiotherapy related software and hardware system research and development built-in electric multi-leaf grating small electronic linear accelerator research and development advanced PET-CT related software and hardware system and advanced image fusion technology. Research and Development of Software and Hardware of Neurosurgery Image Navigation System According to the specific characteristics of synchrotron radiation light source and tokamak device and the general characteristics of nuclear power plant, it provides basic conditions for related physical and biological research such as beam loss monitoring, strong and short pulse mixed field monitoring and nuclear power stationary and constant field monitoring.
The main research contents include: photon energy spectrum measurement and radionuclide identification, photon dose measurement, neutron dose measurement, α β surface pollution measurement, environmental radioactivity background investigation, beam loss monitoring and system improvement of synchrotron radiation light source, research and development of photon/neutron instantaneous dose rate monitoring system under the condition of strong and short pulse photon/neutron mixed field in Tokamak, research and development of biological effect under the condition of strong and short pulse mixed field, teaching and research of nuclear fuel cycle, including separation and evolution of nuclear fission products, and treatment and research of high-level radioactive waste.
The main research contents include: separation of actinides, separation of lanthanides, separation and evolution of long-lived nuclides, treatment of radioactive waste gas, formation of nuclides, research on selective adsorption materials and experiments of microfluidic technology.