| Êíèãà | Ñòðàíèöû äëÿ ïîèñêà |
| Wolf E.L. — Nanophysics and nanotechnology. An introduction to modern concepts in nanoscience | |
| Ito K. — Encyclopedic Dictionary of Mathematics. Vol. 2 | 132.A 351.H |
| Zinn-Justin J. — Quantum field theory and critical phenomena | 56104 |
| Grimaldi R.P. — Discrete and combinatorial mathematics. An introduction | 43 |
| Kisacanin B. — Mathematical problems and proofs. Combinatorics, Number theory, and Geometry | 63 |
| Husemoeller D. — Elliptic curves | 405 |
| Mukamel S. — Principles of Nonlinear Optical Spectroscopy | 514 |
| Huang K. — Statistical Mechanics | 179 |
| Pugovecki E. — Quantum mechanics in hilbert space | 353 |
| Debnath L., Mikusinski P. — Introduction to Hilbert Spaces with Applications | 402 |
| Hogben L. — Handbook of Linear Algebra | 59—10 |
| Serre D. — Handbook of Mathematical Fluid Dynamics, Vol. 1 | 280 |
| Shafarevich I.R., Kostrikin A.I. (ed.) — Basic Notions of Algebra | 162 |
| Browne M.E. — Schaum's outline of theory and problems of physics for engineering and science | 427 |
| Prugovecki E. — Quantum Mechanics in Hilbert Space | 353 |
| Greiner W. — Quantum mechanics. An introduction | 127, 404 |
| Bamberg P.G. — A Course in Mathematics for Students of Physics, Vol. 2 | 803 |
| Thouless D.J. — Topological quantum numbers in nonrelativistic physics | 9, 35, 37, 55, 58, 78 |
| Walecka J.D. — Fundamentals of statistical mechanics | 206, 226—227, 234 |
| Domb C., Green M.S. (eds.) — Phase Transitions and Critical Phenomena (Vol. 1) | 32, 38, 50, 94, 129 |
| Altmann S.L. — Band Theory of Solids: An Introduction from the Point of View of Symmetry | 13 |
| Dorlas T.C. — Statistical mechanics, fundamentals and model solutions | 101, 128 |
| Domb C., Lebowitz J.L. — Phase Transitions and Critical Phenomena (Vol. 19) | see Free fermion approach |
| Ito K. — Encyclopedic Dictionary of Mathematics | 132.A 351.H |
| Lerner K.L., Lerner B.W. — The gale encyclopedia of science (Vol. 6) | 6:3791t, 6:3792, 6:3792t. See also Subatomic particles |
| Galindo A., Pascual P. — Quantum Mechanics Two | II 231, 237, 250, 253 |
| Polkinghorne J.C. — The quantum world | 39f, 89, 93 |
| Collins G.W. — Fundamentals of Stellar Astrophysics | 11, 65 |
| Brown L.S. — Quantum Field Theory | 60, 73 |
| Mukamel S. — Principles of nonlinear spectroscopy | 514 |
| Frampton P. — Dual Resonance Models and Superstrings | 239—245, 247—256, 273—284, 357, 363, 430, 431 |
| Zajac A. — Optics | 53 |
| Guimaraes A.P. — Magnetism and Magnetic Resonance in Solids | 65 |
| Fishbane P.M. — Physics For Scientists and Engineers with Modern Physics | 1151, 1184—1185 |
| Raine D.J., Thomas E.G. — An Introduction to the Science of Cosmology | 130 |
| Wolf-Gladrow D.A. — Lattice-gas cellular automata and lattice Boltzmann models | 40 |
| Bethe H.A., Jackiw R. — Intermediate Quantum Mechanics | 25 |
| Gottfried K., Weisskopf V.F. — Concepts of particle physics (volume 2) | 198—204 |
| Hartle J.B. — Gravity: An Introduction to Einstein's General Relativity | 516, see also “Degenerate tree termions” |
| Rickayzen G. — Green's functions and condensed matter | 341 |
| Fulling S. — Aspects of Quantum Field Theory in Curved Spacetime | 221 (see also “Statistics”) |
| Adair R.K. — The Great Design: Particles, Fields, and Creation | 182, 215, 259, 347, 351 |
| O'Raifeartaigh L. — Group Structure of Gauge Theories | 64, 91, 104 |
| Visser M. — Lorentzian wormholes. From Einstein to Hawking | 35, 83, 190, 285, 286, 335, 373 |
| Rivers R.J. — Path Integral Methods in Quantum Field Theory | 159 |
| Collins P.D., Squires E.J., Martin A.D. — Particle Physics and Cosmology | 1, 35 |
| Balian R. — From Microphysics to Macrophysics: Methods and Applications of Statistical Physics (vol. 1) | 61, 375, 379 |
| Birrell N.D., Davies P.C.W. — Quantum Fields in Curved Space | 1, 17, 260, 285 |
| Wolf E.L. — Nanophysics and nanotechnology: an introduction to modern concepts in nanoscience | 72, 77, 92 |
| Fetter A.L., Walecka J.D. — Quantum theory of many-particle systems | 15—19 |
| Avery J. — Creation and Annihilation Operators | 116, 136 |
| Stahl A. — Physics with tau leptons | 116, 136 |
| Collins P.D.B., Martin A.D., Squires E.J. — Particle Physics and Cosmology | 1, 35 |
| Gray C.G., Gubbins K.E. — Theory of molecular fluids | 9, 245 |
| Carrol B.W., Ostlie D.A. — An introduction to modern astrophysics | 135—136, 294, 563, 564, 1230 |
| Schulman L.S. — Techniques and applications of path integration | 209, 346 |
| ter Haar D. — Elements of Statistical Mechanics | 59, 93 |
| Hoddeson L., Daitch V. — True Genius: The Life and Science of John Bardeen | 60, 218, 221 |
| Shore S.N. — The Tapestry of Modern Astrophysics | see “Distribution function, Fermi — Dirac” |
| Shankar R. — Principles of quantum mechanics | 263 |
| Padmanabhan T. — Theoretical Astrophysics: Volume 1, Astrophysical Processes | 177 |
| Prigogine I. — Proceedings of the International Symposium on Transport. Processes in Statistical Mechanics, held in Brussels,. August 27-31, 1956 | 42, 62, 195 |
| Holmes R.A. — Physical Principles of Solid State Devices | 41 |
| Amit D.J. — Field theory, the renormalization group, and critical phenomena | 43, 67 |
| Phillips P. — Advanced Solid State Physics | 162, 163, 165 |
| Gottfried K., Weisskopf V.F. — Concepts of Particle Physics | 28 |
| Eliezer Sh., Ghatak A., Hora H. — Fundamentals of Equations of State | 5, 13, 318 |
| Attard P. — Therodynamics and Statistical Mechanics: Equilibrium by Entropy Maximisation | 111 |
| Berezin F.A. — Method of Second Quantization | 1 |
| Nouredine Z. — Quantum Mechanics: Concepts and Applications | 444 |
| Leuchs G., Beth T. (eds.) — Quantum Information Processing | 90 |
| Akhiezer A.I., Berestetskii V.B. — Quantum electrodynamics | 241 |
| Ross G. — Grand Unified Theories | 29, 36, 113 |
| Reif F. — Fundamentals of statistical and thermal physics | 333 |
| McQuarrie D.A. — Statistical Mechanics | 13, 69, 101, 160 |
| Bransden B., Joachain C. — Physics of Atoms and Molecules | 106, 233, 452 |
| Alicki R., Lendi K. — Quantum Dynamical Semigroups And Applications | 29, 32 |
| Greiner W., Neise L., Stöcker H. — Thermodynamics and statistical mechanics | 287 |
| Hugh D. Young, Roger A. Freedman — University physics with modern physics | 1521 |
| Cole G.H.A., Woolfson M.M. — Planetary science. The science of planets around stars | 251 |
| Zeidler E. — Applied Functional Analysis: Applications to Mathematical Physics | 363 |
| Kruegel E. — The Physics of Interstellar Dust | 152ff, 194, 466 |
| Greiner W., Neise L., Stocker H. — Thermodynamics and statistical mechanics | 287 |
| Authier A., Lagomarsino S., Tanner B. — X-ray and neutron dynamical diffraction | 374 |
| Salmhofer M. — Renormalization: an introduction | 57, 113 |
| Lemm J.C. — Bayesian field theory | 299—301, 306, 311 |
| Chandler D. — Introduction to modern statistical mechanics | 89, 90, 96—100, 114—116 |
| Sakurai J.J. — Modern quantum mechanics | 361—363 |
| Constantinescu F., Magyari E. — Problems in quantum mechanics | 181 |
| Prikarpatsky A.K., Taneri U., Bogolubov N.N. — Quantum field theory with application to quantum nonlinear optics | 15 |
| Farina J.E.G. — Quantum theory of scattering processes | 55 |
| ter Haar D. — Elements of Statistical Mechanics | 59, 93 |
| Close F. — The New Cosmic Onion: Quarks and the Nature of the Universe | 180, 182 |
| Landau L.D., Lifshitz E.M. — Course of Theoretical Physics (vol.3). Quantum Mechanics. Non-relativistic Theory | 228 |
| Davies P. — The New Physics | 83, 86—87, 486, 489 |
| Kane G.L. — Modern elementary particle physics | 33, 293 |
| Springford M. — Electrons at Fermi surface | 4 |
| Collins P.D.B., Martin A.D., Squires E.J. — Particle Physics and Cosmology | 1, 35 |
| Blin-Stoyle R.J. — Eureka! Physics of particles, matter and the universe | 100 |
| Kaiser G. — Quantum physics, relativity, and complex spacetime: Towards a new synthesis | 293 |
| Reichl L.E. — Modern Course in Statistical Physics | 357 |
| Fetter A.L., Walecka J.D. — Quantum theory of many-particle systems | 15—19 |
| Brandt S., Dahmen H.D. — Quantum mechanics on the personal computer | 85 |
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