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School in Computational Condensed Matter Physics - From Atomistic Simulations to Universal Model Hamiltonians

School in Computational Condensed Matter Physics - From Atomistic Simulations to Universal Model Hamiltonians

ICTP Condensed Matter and Statistical Physics via YouTube Direct link

Systematic Finite-size Scaling Methods for Analyzing Critical Points

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Systematic Finite-size Scaling Methods for Analyzing Critical Points

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School in Computational Condensed Matter Physics - From Atomistic Simulations to Universal Model Hamiltonians

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  1. 1 Blackboard Molecular Dynamics
  2. 2 Exploring Planetary Interiors with Molecular Dynamics
  3. 3 Preliminaries for DMRG: An Exact Diagonalization, Quantum Information
  4. 4 Matrix Product States and DMRG
  5. 5 Numerical Quantum Transport: Introduction to Numerics for Quantum Transport
  6. 6 Strong-coupling Impurity Solvers for Electron-phon Problems
  7. 7 Extended DMFT and GW+DMFT
  8. 8 Hybridization Expansion and Non-crossing Approximation
  9. 9 Foundation of Parallel Systems for High-Performance Computing
  10. 10 Efficient simulations of low-dimensional systems - Lecture 1
  11. 11 Efficient simulations of low-dimensional systems - Lecture 2
  12. 12 Modeling the Quantum Nature of Atomic Nuclei by Imaginary Time Path Integrals - Lecture 1
  13. 13 Representing and understanding patterns in materials and molecules - Lecture 3
  14. 14 Introduction to Monte Carlo Algorithms
  15. 15 Hard Disks: From Classical Mechanics to Statistical Mechanics
  16. 16 Stochastic Series Expansion Method for Simulations of Quantum Spins
  17. 17 Ground-state Projection of Quantum Spins in the Valence Bond Basis
  18. 18 Full Configuration Interaction Quantum Monte Carlo - Lecture 1
  19. 19 Full Configuration Interaction Quantum Monte Carlo - Lecture 2
  20. 20 Sampling and Integration: From Gaussians to Maxwell and Boltzmann
  21. 21 Classical Lattice Spin Models: Ising Model, XY Model
  22. 22 Systematic Finite-size Scaling Methods for Analyzing Critical Points
  23. 23 Out-of-Equilibrium Quantum Monte Carlo Simulation and Quantum Annealing
  24. 24 Full Configuration Interaction Quantum Monte Carlo - Lecture 3
  25. 25 Introduction to path-integral Monte Carlo in continuous space - Lecture 1
  26. 26 Introduction to path-integral Monte Carlo in continuous space - lecture 2
  27. 27 Simulating Strongly Correlated Systems with ALPS - Lecture 1
  28. 28 Excited States From Many Body Perturbation Theory
  29. 29 Total Energies From Many Body Perturbation Theory
  30. 30 Simulating correlated materials on quantum computers - Lecture 1
  31. 31 Simulating correlated materials on quantum computers - Lecture 3
  32. 32 Introduction to (Quantum) Complexity Theory
  33. 33 Tutorial: Scientific Python 1
  34. 34 Introduction to Exact Diagonalization
  35. 35 Exact Diagonalization: Symmetries, Dynamics
  36. 36 Reflecting on the P in HPC a Condensed Matter Physics Perspective
  37. 37 Exact Diagonalization: Applications

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