260047 VU Supersymmetry - where geometry, algebra, and physics meet (2024W)

Supersymmetry is a symmetry that links bosons and fermions. It has become a crucial tool for studying strongly coupled quantum field theories across various space-time dimensions and plays a significant role in string theory. This course aims to explore the mathematical structures underlying theories with extended supersymmetry and connect them to phenomena in quantum field theory.

Course Outline:
1. Supersymmetric Field Theories and Their Ground States/Vacua
2. The Higgs Mechanism, Higgs Vacua, and Their Counting via Hilbert Series
3. Geometry and Algebra of Kähler and Hyper-Kähler Spaces
4. Nilpotent Orbits of sl(N) and their partial order
5. Connecting Geometry and the Higgs Mechanism
6. Coulomb Vacua and the Role of Monopoles
7. Outlook and Future Directions

This course will showcase how classical physics (Higgs vacua) and quantum physics (Coulomb vacua) interact with sophisticated mathematics, such as hyper-Kähler singularities and their stratification. Every mathematical concept will be tied to a specific physical counterpart. The techniques introduced, drawn from geometry, algebra, and physics, have applications beyond the supersymmetric framework.

Lectures will be complemented by exercises designed to reinforce and deepen the material. A strong emphasis will be placed on mastering the computational techniques central to the study of supersymmetric field theories.

Students should be familiar with the content of “Advanced Quantum Mechanics” and have a solid understanding of core theoretical physics topics, particularly quantum mechanics, symmetries, and Noether’s theorem. While not mandatory, it is recommended that students have taken “Introduction to Supersymmetry” or at least “Advanced Particle Physics,” as these courses will provide helpful background for the more advanced topics covered.