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| Ðåçóëüòàò ïîèñêà |
Ïîèñê êíèã, ñîäåðæàùèõ: Fermi energy
| Êíèãà | Ñòðàíèöû äëÿ ïîèñêà | | Wolf E.L. — Nanophysics and nanotechnology. An introduction to modern concepts in nanoscience | | | Greiner W., Muller B., Rafelski J. — Quantum electrodynamics of strong fields | 3, 233 (see also “Fermi surface”) | | Schmalzried H. — Chemical Kinetics of Solids | 172 | | Parr R., Yang W. — Density-functional theory of atoms and molecules | 48, 211 | | Liboff R. — Kinetic Theory | 371, 434 | | Parisi G. — Statistical field theory | 277 | | Jaswon M.A. — The Theory of Cohesion. An Outline of the Cohesive Properties of Electrons in Atoms, Molecules and Crystals | 140, 144, 160, 161, 165, 182, 184, 187 ff | | Huang K. — Statistical Mechanics | 244 | | Honerkamp J. — Statistical Physics | 227 | | Elliott R.J., Gibson A.F. — An Introduction to Solid State Physics and Its Applications | 43, 91, 104, 147 | | Mayer J.E., Mayer M.G. — Statistical Mechanics | 375 | | Balescu R. — Equilibrium and nonequilibrium statistical mechanics | 169, 174 | | Thouless D.J. — Topological quantum numbers in nonrelativistic physics | 35, 69 73, 76, 77, 79, 80 | | Getzlaff M. — Fundamentals of Magnetism | 26, 261 | | Reed M., Simon B. — Methods of Modern mathematical physics (vol. 4) Analysis of operators | 314 | | Eschrig H. — The Fundamentals of Density Functional Theory | 68 | | Walecka J.D. — Fundamentals of statistical mechanics | 239, 241 | | Haken H. — Laser light dynamics (volume 2) | 40 | | Isihara A. — Statistical physics | 305 | | Mihaly L., Martin M.C. — Solid state physics. Problems and solutions | 27, 34, 60, 159 | | Ziman J.M. — Elements of Advanced Quantum Theory | 48, 136, 162 | | Dreizler R.M., Gross E.K.U. — Density Functional Theory: An Approach to the Quantum Many-Body Problem | 56, 83, 99 | | Toda M., Kubo R., Saito N. — Statistical Physics I: Equilibrium Statistical Mechanics, Vol. 1 | 95 | | Altmann S.L. — Band Theory of Solids: An Introduction from the Point of View of Symmetry | 13, 146 | | Dorlas T.C. — Statistical mechanics, fundamentals and model solutions | 187 | | Dittrich T. (ed.), Hanggi P. (ed.), Ingold G.-L. (ed,) — Quantum transport and dissipation | 130, 133, 135, 337, 338 | | Guimaraes A.P. — Magnetism and Magnetic Resonance in Solids | 94—95 | | Fishbane P.M. — Physics For Scientists and Engineers with Modern Physics | 1164—1165, 1167, 1173, 1178, 1185, 1187, 1202 | | Cleland A.N. — Foundations of nanomechanics | 122, 140 | | Dalvit D.A.R., Frastai J., Lawrie I.D. — Problems on statistical mechanics | 11, 4.17, 4.18 | | Bube R.H. — Electronic Properties of Crystalline Solids: An Introduction to Fundamentals | 89 | | Seitz F. — Modern Theory of Solids | 355 | | Unertl W.N. — Physical Structure | 382, 440, 588, 595, 601, 607, 638 | | Cracknell A.P., Wong K.C. — The Fermi Surface: Its Concept, Determination and Use in the Physics of Metals | 19, 60, 117, 383—385, 386, 509 | | Kittel Charles, Kroemer Herbert — Thermal Physics | 155, 183 | | Auerbach A. — Interacting electrons and quantum magnetism | 3 | | Cowan B. — Topics In Statistical Mechanics | 71, 72, 300 | | Balian R. — From Microphysics to Macrophysics: Methods and Applications of Statistical Physics (vol. 1) | 217 | | Gautreau R., Savin W. — Schaum's Outline of Modern Physics | 287, 293, 315 | | Wolf E.L. — Nanophysics and nanotechnology: an introduction to modern concepts in nanoscience | 5, 62, 72, 92 | | Pomraning G.C. — The equations of radiation hydrodynamics | 166 | | Perkins D.H. — Particle Astrophysics | 198 | | Junker G. — Supersymmetric Methods in Quantum and Statistical Physics | 113 | | Avery J. — Creation and Annihilation Operators | 41, 46 | | Stahl A. — Physics with tau leptons | 41, 46 | | Carrol B.W., Ostlie D.A. — An introduction to modern astrophysics | 563—565 | | ter Haar D. — Elements of Statistical Mechanics | 128 | | Economou E.N. — Green's Functions in Quantum Physics | 127 | | Greiner W. — Quantum mechanics: special chapters | 226,294 | | L. Pitaevskii, Stringari S. — Bose-Einstein Condensation | 348 | | Volovik G. — Artificial black holes | 92 | | Hume-Rothery W. — Atomic Theory for Students of Metallurgy | 167 | | Holmes R.A. — Physical Principles of Solid State Devices | 80, 82 | | Pathria P.K. — Statistical Mechanics | 198, 200, 202, 205, 210, 214—215, 219, 229—230 | | Measures R.M. — Laser remote sensing. Fundamentals and applications | 197 | | Fox M. — Optical properties of solids | 99, 101, 106, 151-3, 156-7, 271-3, 280-1 | | Phillips P. — Advanced Solid State Physics | 39, 216, 223, 244-245 | | Anisimov S.I., Khokhlov V.A. — Instabilities in Laser-matter interaction | 64 | | Ashcroft N.W., Mermin N.D. — Solid State Physics | see also "Chemical potential" | | Mourachkine A. — High-Temperature Superconductivity in Cuprates: The Nonlinear Mechanism and Tunneling Measurements | 15, 26, 169, 211 | | Richter K. — Semiclassical theory of mesoscopic quantum systems | 12 | | Dekker A.J. — Solid State Physics | 214, 215, 224, 231 | | Azaroff L.V. — Introduction to Solids | 241, 282 | | Mayer J.E., Goeppert Mayer M. — Statistical mechanics | 375 | | Appenzeller I. (ed.), Habing H.J. (ed.), Léna P. (ed.) — Evolution of Galaxies Astronomical Observations | 309 | | Povh B., Rith K., Scholz C., Zetsche F. — Particles and nuclei. An introduction to the Physical Concepts | 244 | | Papadopoulos G.J. (ed.), Devreese J.T. (ed.) — Path integrals and their applications in quantum, statistical, and solid state physics | 110 | | Wurfel P. — Physics of Solar Cells: From Principles to New Concepts | 56, 58 | | Bohr A., Mottelson B.R. — Nuclear Structure (Vol. 1): Single-Particle Motion | 141 | | Reif F. — Fundamentals of statistical and thermal physics | 388, 391 | | Bransden B., Joachain C. — Physics of Atoms and Molecules | 310 | | Goldsmid H.J. (ed.) — Problems in solid state physics | 11.1, 11.3, 11.4, 12.7, 13.2, 14.1 | | Marder M.P. — Condensed matter physics | 142 | | Singh J. — Semiconductor Optoelectronics: Physics and Technology | 96 | | Leighton R.B. — Principles of Modern Physics | 341 | | Davies J.H. — The physics of low-dimensional semiconductors : an introduction | 37 | | Datta S. — Electronic transport in mesoscopic systems | 3, 8,12—14, 21, 27, 45—46, 87, 176, 185, 223, 266, 268, 271, 274 | | Grosso G. (Ed), Parravicini G.P. (Ed) — Solid State Physics | 82, 93 | | HarrisR. — Nonclassical physics: beyond Newton's view | 370—371, 374—375, 376—377, 438 | | Morkoc H. — Advanced semiconductor and organic nano-techniques | 8, 14, 32 | | Ashby N., Miller S.C. — Principles of modern physics | 315, 322, 324 | | Mott N.F. — Metal-insulator transitions | 70 | | Kruegel E. — The Physics of Interstellar Dust | 87, 158, 193ff, 211 | | Chandler D. — Introduction to modern statistical mechanics | 98 | | Hassani S. — Mathematical Methods: for Students of Physics and Related Fields | 677 | | Dolan T.J. — Fusion Research: Principles, Experiments and Technology | 447 | | Morandi G. — Statistical Mechanics: An Intermediate Course | 304 | | ter Haar D. — Elements of Statistical Mechanics | 128 | | Greiner W., Maruhn J. — Nuclear models | 101, 244, 284, 290, 294, 302, 304, 309, 316, 321, 340 | | Davies P. — The New Physics | 273, 279, 284 | | Askeland D.R. — The Science and Engineering of Materials | 624 | | Springford M. — Electrons at Fermi surface | 5, 21, 346 | | Reichl L.E. — Modern Course in Statistical Physics | 393, 398 | | Ichimaru S. — Statistical Plasma Physics, Volume I: Basic Principles (Frontiers in Physics, Vol 87) (v. 1) | 7, 26 | | Kittel C. — Introduction to solid state physics | 145 | | Plischke M., Bergersen B. — Equilibrium statistical physics | 45 | | Lilley J.S. — Nuclear physics: principles and applications | 39, 335 | | Honerkamp J. — Statistical physics: an advanced approach with applications | 227 | | Liboff R.L. — Introductory quantum mechanics | 35, 62p, 293 | | Rosser W.G.V. — An introduction to statistical physics | 285, 288, 294, 300, 306, 308 |
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