Schedule: Difference between revisions
From phys800
Jump to navigationJump to search
| Line 10: | Line 10: | ||
===Fall 2023=== | ===Fall 2023=== | ||
*B. K. Nikolić, [[Media:PHYS800_hubbard_dimer.pdf|From Hubbard dimer to effective antiferromagnetic Hubbard model for two spins]] | |||
*B. K. Nikolić, [[Media:PHYS800_magnons.pdf|Ground state and low-energy magnon excitations of ferro- and antiferromagnets]] | |||
* F. Garcia-Gaitan, Introduction to DMRG. | * F. Garcia-Gaitan, Introduction to DMRG. | ||
* F. Garcia-Gaitan, Antiferromagnetic and altermagnetic magnons. | * F. Garcia-Gaitan, Antiferromagnetic and altermagnetic magnons. | ||
Revision as of 11:27, 29 February 2024
Fall 2022
- B. K. Nikolic, One-dimensional models of adiabatic charge and spin pumping.
- J. A. Fernandez Sanchez, Schwinger-Keldysh ("in-in") vs. Feynman ("in-out") path integral with harmonic oscillator examples.
- L. H. Mai, Introduction to the Lindblad master equation with QuTiP examples [Jupyter Notebook].
- L. Herrera, Numerically “exact” approach to open quantum dynamics: The hierarchical equations of motion. [Jupyter Notebook].
Spring 2023
- J. Varela-Manjarres, Floquet engineering of quantum systems.
- S. J. V. Urbano, Application of the Helfrich elasticity theory to the morphology of red blood cells.
Fall 2023
- B. K. Nikolić, From Hubbard dimer to effective antiferromagnetic Hubbard model for two spins
- B. K. Nikolić, Ground state and low-energy magnon excitations of ferro- and antiferromagnets
- F. Garcia-Gaitan, Introduction to DMRG.
- F. Garcia-Gaitan, Antiferromagnetic and altermagnetic magnons.
- F. Garcia-Gaitan, Effective spin Hamiltonian from light-driven Hubbard model.
Spring 2024
- F. Reyes-Osorio, Schwinger-Keldysh field theory.
- K. J. Rueda-Espinosa, Jaynes–Cummings model.
