Selected Readings: Difference between revisions
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* [http://www.amazon.com/Electrodynamics-Solids-Optical-Properties-Electrons/dp/0521597269 Electrodynamics of Solids: Optical Properties of Electrons in Matter], Martin Dressel , George Gruner | * [http://www.amazon.com/Electrodynamics-Solids-Optical-Properties-Electrons/dp/0521597269 Electrodynamics of Solids: Optical Properties of Electrons in Matter], Martin Dressel , George Gruner | ||
* [http://bcsbec.df.unicam.it/files/LaRNC11_N12(1988).pdf Application of the Green’s functions method to the study of the optical properties of semiconductors], G. Strinati | * [http://bcsbec.df.unicam.it/files/LaRNC11_N12(1988).pdf Application of the Green’s functions method to the study of the optical properties of semiconductors], G. Strinati | ||
* [https://iopscience.iop.org/article/10.1238/Physica.Topical.109a00141 Effects of the Electron–Hole Interaction on the Optical Properties of Materials: the Bethe–Salpeter Equation], G. Bussi | * [https://iopscience.iop.org/article/10.1238/Physica.Topical.109a00141 Effects of the Electron–Hole Interaction on the Optical Properties of Materials: the Bethe–Salpeter Equation], G. Bussi |
Revision as of 21:00, 23 February 2023
General Theory
- Theoretical spectroscopy, M. Gatti
- Energy Loss Spectroscopy, F. Sottile
Many-body Theory
- PhD lectures: MBPT and Yambo, L. Chiodo et al.
- Introduction to Many Body Physics, Piers Coleman
- Pedagogical introduction to equilibrium Green's functions: condensed matter examples with numerical implementations, Mariana M. Odashima et al.
- Quantum Condensed Matter Physics, Chetan Nayak
The GW method
- The GW methods, F. Aryasetiawan and O. Gunnarsson
- Many-Body Perturbation Theory: The GW Approximation, Christoph Friedrich and Arno Schindlmayr
- Correlation effects in solids from first principles, Aryasetiawan Ferdi
- The GW Compendium: A Practical Guide to Theoretical Photoemission Spectroscopy, Dorothea Golze, Marc Dvorak and Patrick Rinke
- Hedin Equations, GW, GW+DMFT, and All That, K. Held, C. Taranto, G. Rohringer, A. Toschi
Density Functional Theory
- The ABC of DFT, Kieron Burke
- Density Functional Theory -- an introduction, Nathan Argaman, Guy Makov
- A Practical Introduction to Density Functional Theory, Louk Rademaker
- Density Functionals for non relativistic Coulomb Systems, J. Perdew and S. Kurth
- A bird's-eye view of density-functional theory, Klaus Capelle
- Phonons and related properties of extended systems from density-functional perturbation theory, S. Baroni, S. de Gironcoli, A. Dal Corso, P. Giannozzi
- Density functional approach to the many-body problem, Robert van Leeuwen
TDDFT
- Electronic Excitations: Density-Functional VS Many-body Green's, G. Onida, L. Reining, A. Rubio
- A guided tour of time-dependent density functional theory, K. Burke and E.K.U. Gross
- Density functional theory of time-dependent phenomena, E.K.U. Gross , J.F. Dobson , and M. Petersilka
- Time-dependent density-functional theory for extended systems, S. Botti et al.
- Density Functional Theory for Electronic Excited States, John M. Herbert
Non-equilibrium Green's function
- An Introduction to Nonequilibrium Green Functions, Robert van Leeuwen
- An Introduction to Nonequilibrium Many-Body Theory, Joseph Maciejko
Theoretical Spectroscopy
- Electrodynamics of Solids: Optical Properties of Electrons in Matter, Martin Dressel , George Gruner
- Application of the Green’s functions method to the study of the optical properties of semiconductors, G. Strinati
- Effects of the Electron–Hole Interaction on the Optical Properties of Materials: the Bethe–Salpeter Equation, G. Bussi
- FreeScience.info--> Spectroscopy
Computer Programming
- Fortran90 for Fortran77 Programmers, Clive Page
- Fortran 90 Lectures, John Mahaffy
- Bash Guide for Beginners, Machtelt Garrels
- Programming in C UNIX System Calls and Subroutines using C, A. D. Marshall
- The C Book, Mike Banahan, Declan Brady and Mark Doran