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Поиск книг, содержащих: Hubbard model
| Книга | Страницы для поиска | | Anderson P.W. — Basic notions of condensed matter physics | | | Gomez C., Ruiz-Altaba M., Sierra G. — Quantum Groups in Two-Dimensional Physics | 244, 270 | | Mahan G.D. — Many-particle physics | 28, 57, 78, 957 | | Parr R., Yang W. — Density-functional theory of atoms and molecules | 97 | | Fradkin E. — Field theories of condensed matter systems | 5, 21, 46, 92 | | Moriya T. — Spin fluctuations in itinerant electron magnetizm | 17 | | Wagner M. — Unitery Transformations in Solid State Physics | 328(t) | | Dreizler R.M., Gross E.K.U. — Density Functional Theory: An Approach to the Quantum Many-Body Problem | 147, 149 | | Giamarchi T. — Quantum Physics in One Dimension | 156, 200 | | Rickayzen G. — Green's functions and condensed matter | 274—282 | | Auerbach A. — Interacting electrons and quantum magnetism | 8, 21 | | Anderson P.W. — The theory of superconductivity in the high-Tc curprates | 4, 5, 40, 46—47, 428, see “Mott — Hubbard upper, lower Hubbard band” | | Beaurepaire E., Bulou H., Scheurer F. — Magnetism: A Synchrotron Radiation Approach | 9 | | Nagaosa N. — Quantum field theory in strongly correlated electronic systems | 76, 89 | | Economou E.N. — Green's Functions in Quantum Physics | 327—331, 333 | | Tsvelik A.M. — Quantum field theory in condensed matter physics | 269 | | Daniel C. Mattis — The theory of magnetism made simple: an introduction to physical concepts and to some useful mathematical methods | 154, 315-317 | | Martin R.M. — Electronic Structure: Basic Theory and Practical Methods | 161, 171, 422 | | Phillips P. — Advanced Solid State Physics | 149, 151 | | Ashcroft N.W., Mermin N.D. — Solid State Physics | 685 | | Steeb W., Hardy Y. — Problems and Solutions in Quantum Computing and Quantum Information | 128 | | Farges J. (ed.) — Organic conductors: fundamentals and applications | 5, 29—64, 230, 239, 274—288, 312, 319, 330, 373, 406, 415, 416, 422, 454—459, 487, 507, 589, 590, 764, see also "Interactions" | | Tsvelik A.M. — Quantum field theory in condensed matter physics | 269 | | Anderson J.B. — Quantum Monte Carlo: Origins, Development, Applications | 76 | | Marder M.P. — Condensed matter physics | 772—776, 779 | | Morkoc H. — Advanced semiconductor and organic nano-techniques | 13 | | Salmhofer M. — Renormalization: an introduction | 114 | | Binder K., Heermann D.W. — Monte Carlo Simulation in Statistical Physics | 154, 155, 157 | | Bok J., Deutscher G., Pavuna D. — The gap symmetry and fluctuations in High-Tc conductors | 74, 79, 113, 321 | | Bok J., Deutscher G., Pavuna D. — The gap symmetry and fluctuations in High-Tc conductors | 74, 79, 113, 321 | | Bruss D. (ed.), Leuchs G. (ed.) — Lectures on Quantum Information | 406, 461, 464 | | H. Fehske, R. Schneider, A. Weile — Computational Many-Particle Physics | 455, 473, 480, 484—490, 496, 529—537, 540, 543, 570, 574, 632, 655 |
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