Advanced Statistical Physics (P817), Spring 2020

Instructor: Romain Vasseur, Assistant Professor
office: Hasbrouck 405A
email: rvasseur[at]umass[dot]edu
office hours: by appointment and email, or visit my office

Lectures: MW 4.00-5.15pm, room: Has 136

Suggested reading materials:

• Scaling and Renormalization in Statistical Physics, John Cardy,  Cambridge University Press
• Statistical Physics of Fields, Kardar, Cambridge University Press
• Lectures on Phase Transitions and the Renormalization Group, Nigel Goldenfeld,  Frontiers in Physics Series (Vol. 85), Westview Press
• Principles of Condensed Matter Physics, P.M. Chaikin & T.C. Lubensky, Cambridge University Press
• Phase transitions and Renormalization Group, Jean Zinn-Justin, Oxford Graduate Texts

Website: https://websites.umass.edu/rvasseur/teaching/advanced-statistical-physics-p817-spring-2020. Course materials will also be made available on Moodle.

Grading:
The course grade will be based 65% on the homework and 35% on a final term paper.

Topics:

• Introduction: Critical phenomena and simple models. Mean-field theory.
• Ginzburg-Landau theory: fluctuations, Ginzburg criterion, upper/lower critical dimensions, Goldstone modes.
• The Renormalization Group
• The perturbative RG:
  • Operator product expansions
  • epsilon expansion
  • O(N) model and Large N limit
• XY model: Topological defects, Coulomb gas and Berezinskii-Kosterlitz–Thouless transition
• Advanced topics (time permitting):
  • Nonlinear sigma model
  • Random Systems
  • (Brief) Introduction to conformal field theory

Lecture Notes:

1. Critical Phenomena
2. Ginzburg-Landau theory & Fluctuations
3. The Renormalization Group
4. Perturbative RG
5. KT transition
6. Nonlinear sigma model
7. Disordered systems
8. CFT

Problem Sets:

• HW1_MeanField due Feb 7 by 5pm
• HW2_GinzburgLandau due Feb 28 by 5pm
• HW3_Scaling due March 23 by 5pm
• HW4_perturbative_RG due April 10
• HW5_KT due May 1

Solutions available on Moodle, or upon request by email.

Schedule:

• 1/22: Intro to critical phenomena, Chapter 1: pages 1-4
• 1/27: Mean-field theory, Chapter 1: pages 5-8
• 1/29: Landau-Ginzburg theory and saddle-point, Chapter 2: pages 1-4
• 2/3: Mean-field critical exponents and correlation functions, Chapter 2: pages 5-7 + appendix page 17
• 2/5: Ginzburg criterion and functional Gaussian integrals, Chapter 2: pages 8-9 + appendix pages 15-16 on Gaussian integrals
• 2/10: Fluctuations about the saddle point, upper/lower critical dimension, Peierls’ argument. Chapter 2: pages 9-12.
• 2/12: Goldstone modes and Mermin-Wagner theorem, Chapter 2: pages 12-14.
• 2/18: Block spins, RG transformations, Chapter 3: pages 1-3.
• 2/19: RG flows, scaling variables, universality and scaling, Chapter 3: page 4-7.
• 2/24: Scaling and critical exponents, corrections to scaling and finite size scaling, Chapter 3: pages 7-9.
• 3/2: Scaling operators and correlation functions, start real space RG for Ising, Chapter 3: pages 10-12.
• 3/3: Real space RG for the 2D Ising model, dimensional analysis of LG theory. Perturbative RG: general idea. Chapter 3: pages 12-14. Chapter 4: page 1.
• 3/9: OPEs and 1-loop perturbative RG equations. Chapter 4: pages 2-4.
• 3/11: Gaussian fixed points, Normal order and gaussian OPEs. Chapter 4: pages 5-7.
• 3/12: large N limit of the O(N) model. Chapter 4: pages 12-14.
• SPRING BREAK. Summary latex Notes
• 3/23: Gaussian OPEs and Wilson-Fisher fixed point. Chapter 4: pages 7-9.
• 3/25: Epsilon expansion, irrelevant operators and O(N) model. Chapter 4: pages 9-11.
• 3/30: Dangerously irrelevant variables and phi^4 theory for d>4. XY Model: Monte Carlo Simulations, High T expansion. Chapter 4: page 15. Chapter 5: pages 1-2.
• 4/1: XY Model: Low T expansion, quasi-long range order, vortices and free energy argument. Chapter 5: pages 2-4.
• 4/6: Dipoles and Coulomb gas mapping. Chapter 5: pages 5-7.
• 4/8: Sine-Gordon theory and vortex operators. Chapter 5: pages 7-9.
• 4/13: Stiffness renormalization. Chapter 5: pages 9-11.
• 4/15: RG analysis of the KT transition, scaling. Chapter 5: pages 11-15.
• 4/22: Non-linear sigma model, beta function. Chapter 6: pages 1-3.
• 4/27: O(N) model in d=2+epsilon. Disordered systems and replica trick. Chapter 6: page 4. Chapter 7: pages 1-2.
• 4/29: Harris criterion. A few words about conformal invariance. Chapter 7: page 3.
• iPad notes (online lectures): link

Suggestions for final project:

• Disordered systems: replica trick, Harris criterion, Imry-Ma argument
• RG in high-energy physics vs statistical mechanics
• Quantum criticality: quantum to classical mapping, example: transverse field Ising chain
• Exact solution of the 2D Ising model using Majorana fermions (possibility to collaborate with “quantum criticality”)
• Percolation: mapping onto Potts model, critical behavior
• Polymers: limit n–> 0 of the O(n) model, critical behavior
• Surface critical behavior (Cardy)
• Topological terms in non-linear sigma models
• Spin glasses
• Momentum-shell RG (compare to OPE approach developed in class)
• Critical dynamics: reaction diffusion models (Cardy)
• Monte Carlo simulations and finite-size scaling: write a MC code for the 2D Ising model and extract critical exponents
• Dynamic of growing surfaces, KPZ equation (Kardar)
• Integrable statistical mechanics models
• Conformal Field Theory (Finite size scaling)
• CFT (global conformal invariance, correlation functions + overview in 2d)
• Neural networks: Hopfield model
• Scaling in non-equilibrium systems (Goldenfeld)
• Lee-Yang theorem
• Caldeira-Leggett model (qubit in dissipative environment)