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week1 [2014/07/14 04:06] bogner |
week1 [2014/07/28 15:14] schunck [Friday, July 18] |
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==== Daily Schedule ==== | ==== Daily Schedule ==== | ||
- | * 9:00-10:30 Lectures | + | * 09:00-10:30 Lectures |
* 10:30-11:00 Coffee | * 10:30-11:00 Coffee | ||
* 11:00-12:30 Lectures | * 11:00-12:30 Lectures | ||
- | * 12:30-2:00 Lunch | + | * 12:30-14:00 Lunch |
- | * 2:00-3:30 Exercises | + | * 14:00-15:30 Exercises |
- | * 3:30-4:00 Coffee | + | * 15:30-16:00 Coffee |
- | * 4:00-6:00 Computational Project/Exercises | + | * 16:00-18:00 Computational Project/Exercises |
- | * | + | |
==== Week 1: Basic techniques of quantum many-body physics ==== | ==== Week 1: Basic techniques of quantum many-body physics ==== | ||
==== Monday, July 14 ==== | ==== Monday, July 14 ==== | ||
* Welcome/Introductory Remarks | * Welcome/Introductory Remarks | ||
- | * [[dario1|Dario Vretenar 1]]: Reminder of advanced quantum mechanics: Coordinate and momentum representations of the Hilbert space, discrete bases, operators, Schrodinger equation, spin, isospin, Dirac equation | + | * {{qm.pdf|Dario Vretenar 1}}: Reminder of advanced quantum mechanics: Coordinate and momentum representations of the Hilbert space, discrete bases, operators, Schrodinger equation, spin, isospin, Dirac equation |
* {{computing.pdf|Computational Projects}}: Requirements for the computational projects, crash courses on Makefile and the git version control system. | * {{computing.pdf|Computational Projects}}: Requirements for the computational projects, crash courses on Makefile and the git version control system. | ||
+ | * {{:talentdftguides.pdf|}}: More information on Git, Unit tests, Object Orientation, and MPI/OpenMP | ||
==== Tuesday, July 15 ==== | ==== Tuesday, July 15 ==== | ||
- | * [[scott1|Scott Bogner 1]]: Second quantization: Fermions and bosons, Fock space, Wick theorem, equivalence between representations | + | * {{secondquantizationshorter.pdf|Scott Bogner 1}}: In this lecture I review some basic concepts and tools of many-body theory (symmetrization postulate for N-body states, Fock space and second quantization, Wick's theorem, particle-hole picture). The treatment I give is standard, and may be found in any of the textbooks in the References. |
+ | * Reminder on {{AngMom.pdf|angular momentum algebra}} | ||
==== Wednesday, July 16 ==== | ==== Wednesday, July 16 ==== | ||
- | * [[scott2|Scott Bogner 2]]: Hartree-Fock (HF) theory: product states, density matrices, variational principle, Thouless theorem, Koopman's theorem | + | * {{hartreefock3.pdf|Scott Bogner 2}}: Hartree-Fock (HF) theory: product states, density matrices, variational principle, Thouless theorem, Koopman's theorem |
==== Thursday, July 17 ==== | ==== Thursday, July 17 ==== | ||
- | * [[peter1|Peter Ring 1]]: Pairing Correlations: Spontaneous symmetry breaking, BCS approximation, pairing tensor, Hartree-Fock-Bogoliubov (HFB) theory | + | * {{ring-pairing.pdf|Peter Ring 1}}: Pairing Correlations: Spontaneous symmetry breaking, seniority model, BCS approximation, pairing tensor, Hartree-Fock-Bogoliubov (HFB) theory |
==== Friday, July 18 ==== | ==== Friday, July 18 ==== | ||
- | * [[peter2|Peter Ring 2]]: Random Phase Approximation (RPA): Time-dependent Hartree-Fock (TDHF) theory, linear response, stability matrix | + | * {{ring-rpa.pdf|Peter Ring 2}}: Random Phase Approximation (RPA): Time-dependent Hartree-Fock (TDHF) theory, linear response, stability matrix |