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Last update: T_KFES (15.05.2014)
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Last update: Mgr. Jindřich Kolorenč, Ph.D. (07.06.2019)
Oral exam. |
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Last update: Mgr. Jindřich Kolorenč, Ph.D. (29.04.2019)
A. Szabo, N. S. Ostlund, Modern quantum chemistry, Dover Publications, 1996. G. F. Giuliani, G. Vignale, Quantum theory of the electron liquid, Cambridge University Press, 2005. E. A. Hylleraas, Neue Berechnung der Energie des Heliums im Grundzustande, sowie des tiefsten Terms von Ortho-Helium, Z. Physik 54, 347–366 (1929); English translation of this paper is a part of the book H. Hettema, Quantum chemistry: Classic scientific papers, World Scientific, 2000. P. Fulde, Correlated electrons in quantum matter, World Scientific, 2012. B. L. Hammond, W. A. Lester, jr., P. J. Reynolds, Monte Carlo methods in ab initio quantum chemistry, World Scientific, 1994. I. Kosztin, B. Faber, K. Schulten, Introduction to the diffusion Monte Carlo method, Am. J. Phys. 64, 633–644 (1996). J. Kolorenč, L. Mitas, Applications of quantum Monte Carlo methods in condensed systems, Rep. Prog. Phys. 74, 026502 (2011). |
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Last update: Mgr. Jindřich Kolorenč, Ph.D. (07.06.2019)
Exam has only an oral part. Requirements correspond to the syllabus to the extent presented during lectures. |
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Last update: Mgr. Jindřich Kolorenč, Ph.D. (29.04.2019)
The aim of the course is to illustrate selected general principles on simple examples, both in tight-binding lattice models and in the direct space.
Hydrogen molecule as the simplest example of strong electron-electron correlations:
Magnetic impurity in a metal:
Correlated metal:
Helium atom and helium-like ions:
Variational Monte Carlo:
Diffusion Monte Carlo: |