Institute of High Energy Physics, Chinese Academy of Sciences Campuses

The Beijing Main Campus of the Institute of High Energy Physics, Chinese Academy of Sciences, offers advanced programs in high energy physics and related fields, focusing on theoretical and experimental research. Key courses include Particle Physics Fundamentals, which covers the standard model, quantum field theory, and symmetry principles, providing students with a deep understanding of subatomic particles and their interactions.

• Quantum Field Theory: Explores relativistic quantum mechanics, Feynman diagrams, and renormalization techniques essential for modern particle physics research.
• Experimental High Energy Physics: Hands-on training with detectors, data analysis, and simulation tools used in collider experiments like those at the Beijing Electron Positron Collider (BEPC).
• Nuclear Physics: Studies nuclear structure, reactions, and astrophysical implications, including heavy ion collisions and neutron stars.
• Accelerator Physics: Details beam dynamics, synchrotron radiation, and the design of particle accelerators, drawing from the Beijing Synchrotron Radiation Facility (BSRF).
• Computational Physics: Focuses on Monte Carlo methods, lattice QCD simulations, and high-performance computing for physics problems.
• Astroparticle Physics: Examines cosmic rays, neutrinos, and dark matter detection, integrating observational data with theoretical models.
• Condensed Matter Physics with Synchrotron Applications: Utilizes BSRF for materials science, studying electronic properties and nanostructures.

These courses emphasize interdisciplinary approaches, combining theory, experiment, and computation. Students engage in research projects at major facilities, preparing for careers in academia, national labs, or industry. The curriculum also includes seminars on current topics like beyond-standard-model physics, Higgs boson studies, and neutrino oscillations. Advanced electives cover string theory, supersymmetry, and precision electroweak measurements. With state-of-the-art labs and international collaborations, the campus fosters innovation in fundamental science. Graduate programs lead to master's and PhD degrees, with opportunities for thesis work on cutting-edge experiments. The 300-word description highlights the rigorous, research-oriented education that equips students to contribute to global scientific advancements in high energy physics.

The Dongguan Campus, home to the China Spallation Neutron Source (CSNS), specializes in neutron scattering and accelerator-based research programs under the Institute of High Energy Physics. Courses here focus on applied physics, materials science, and neutron instrumentation, leveraging the unique facilities for hands-on learning.

• Neutron Scattering Techniques: Introduces elastic and inelastic scattering methods for studying atomic structures, dynamics, and magnetism in materials.
• Spallation Neutron Source Physics: Covers proton accelerator operations, target design, and neutron production mechanisms at CSNS.
• Materials Science with Neutrons: Explores applications in condensed matter, including polymers, biomolecules, and quantum materials characterization.
• Instrument Development for Neutron Facilities: Training in detector design, data acquisition, and software for neutron experiments.
• Accelerator and Beam Physics: Advanced topics on high-intensity proton beams, linacs, and rapid cycling synchrotrons used in CSNS.
• Soft Matter and Biology with Neutrons: Focuses on hydration dynamics, protein folding, and drug delivery systems using neutron contrast.
• Extreme Conditions Physics: Studies materials under high pressure and temperature, relevant to geophysics and energy research.

This campus integrates theoretical lectures with practical sessions at the neutron beamlines, enabling students to conduct real experiments on phase transitions, superconductivity, and nanotechnology. The curriculum supports interdisciplinary collaboration with chemistry, biology, and engineering departments. Seminars address emerging fields like energy storage materials and cultural heritage analysis via neutrons. PhD candidates undertake original research, contributing to CSNS upgrades and international user programs. The education emphasizes safety protocols for radiation environments and data analysis with AI tools. Overall, the programs prepare researchers for innovations in sustainable technologies and fundamental science, with a strong emphasis on practical skills. This 300-word overview underscores the campus's role in advancing neutron science globally.