| Êíèãà | Ñòðàíèöû äëÿ ïîèñêà |
| Wolf E.L. — Nanophysics and nanotechnology. An introduction to modern concepts in nanoscience | |
| Crowell B. — The modern revolution in physics | |
| Gilbert J., Murray M. — Clifford Algebras and Dirac Operators in Harmonic Analysis | 296 |
| Majid S. — Foundations of Quantum Group Theory | xiv, 71, 213, 250, 347, 455, 501 |
| Weinstock R. — Calculus of variations with applications to physics & engineering | 262n., 271 |
| Ward R.S., Wells R.O. — Twistor geometry and field theory | 242 |
| Benson D. — Mathematics and music | 63 |
| Goldstein H., Poole C., Safko J. — Classical mechanics | 380 |
| Landsman N.P. — Mathematical topics between classical and quantum mechanics | 2 |
| Naber G.L. — The geometry of Minkowski spacetime: an introduction to the mathematics of the special theory of relativity | 91 |
| Mukamel S. — Principles of Nonlinear Optical Spectroscopy | 16 |
| Huang K. — Statistical Mechanics | 180 |
| Gracia-Bondia J.M., Varilly J.C., Figueroa H. — Elements of Noncommutative Geometry | 111 |
| Cannas da Silva A., Weinstein A. — Geometric Models for Noncommutative Algebra | 146 |
| Browne M.E. — Schaum's outline of theory and problems of physics for engineering and science | 403 |
| McMano D., Topa D.M. — A Beginner's Guide to Mathematica | 495 |
| Rockmore D. — Stalking the Riemann Hypothesis: The Quest to Find the Hidden Law of Prime Numbers | 187—188 |
| Feynman R.P., Leighton R.B., Sands M. — The Feynman lectures on physics (vol.1) | 5—10,6—10,17—8,37—11 |
| Planck M. — Introduction to Theoretical Physics | 330 |
| Bates L.F. — Modern Magnetism | 17, 54 |
| Dorlas T.C. — Statistical mechanics, fundamentals and model solutions | 75, 93 |
| Lerner K.L., Lerner B.W. — The gale encyclopedia of science (Vol. 6) | 1:362, 5:3096—3097, 6:3756, 6:3877 |
| Jahne B. — Digital Image Processing | 150 |
| Zajac A. — Optics | 7, 51, 52, 585 |
| Fishbane P.M. — Physics For Scientists and Engineers with Modern Physics | 301, 504—505, 887, 965, 1113, 1118, 1123, 1131, A-2 |
| Bratteli O., Robinson D.W. — Operator Algebras and Quantum Statistical Mechanics (vol. 1) | 4 |
| Kythe P.K. — Fundamental Solutions for Differential Operators and Applications | 79, 356 |
| Born M. — Atomic Physics | 70 |
| Hilborn R.C. — Chaos and nonlinear dynamics | 491 |
| Kyle T.G. — Atmospheric transmission, emission and scattering | 157 |
| Zeldovich Ya.B., Yaglom I.M. — Higher Math for Beginners | 406, 410 |
| Young M. — Optics and Lasers: Including Fibers and Optical Waveguides | 4.2.1 |
| Yulsman T. — Origins. The quest for our cosmic roots | 45 |
| Unertl W.N. — Physical Structure | 146 |
| Abraham Taylor — An introduction to X-ray metallography | 9, 84, 169 |
| Schiff L.I. — Quantum mechanics | 2, 7 |
| Lieberman M.A., Lichtenberg A.J. — Principles of Plasma Discharges and Materials Processing | 65 |
| Rockmore D. — Stalking the Riemann Hypothesis | 187—188 |
| Meyerhof W.E. — Elements of Nuclear Physics | 13 |
| Herbert C.G., Johnstone R.A.W. — Mass Spectrometry Basics | 117 |
| Stoner E.C. — Magnetism and Atomic Structure with 56 diagrams | 92 |
| Eddington A. — The Internal Consitution of the Stars | 46, 395 |
| Barrow J.D., Tipler F.J. — Anthropic Cosmological Principle | 222—223, 292 |
| Goodman J.W. — Introduction to Fourier Optics | 64 |
| Mason G.W., Griffen D.T., Merrill J. — Physical Science Concepts | 128-129, 131, 138, 143, 147-148, 151, 157, 370-371 |
| Streetman B.G. — Solid State Electronic Devices | 31, 438 |
| Carrol B.W., Ostlie D.A. — An introduction to modern astrophysics | 73, 116, 118, 121 |
| De Finetti B. — Theory of probability (Vol. 2) | 319 |
| Slater J.C. — Introduction To Chemical Physics | 39 |
| D'Inverno R. — Introducing Einstein's Relatvity | 49 |
| Bates D.R. — Quantum Theory | 3 |
| Berezin F.A., Shubin M.A. — The Schroedinger equation | 1, 6 |
| Fogiel M. — The optics problem solver | 3—8 to 3—10 |
| Goodman J.W. — Statistical Optics | 468, 487 |
| Cotterill R.M.J. — Biophysics: An Introduction | 65, 269, 344 |
| Guru B.S., Hiziroğlu H.R. — Electromagnetic Field Theory Fundamentals | 203 |
| Sachs R.K., Wu H. — General relativity for mathematicians | 131, 143, 199 |
| Measures R.M. — Laser remote sensing. Fundamentals and applications | 20 |
| Carmeli M. — Classical Fields: General Gravity and Gauge Theory | 102, 259 |
| Eliezer Sh., Ghatak A., Hora H. — Fundamentals of Equations of State | 27 |
| Leverenz H.W. — An introduction to luminescence of solids | 4, 150 |
| Baez J.C., Muniain J.P. — Gauge theories, knots, and gravity | 135, 152 |
| Azaroff L.V. — Introduction to Solids | 75, 435 |
| Marks R.J.II. — The Joy of Fourier | 186, 691 |
| Harman T.L., Dabney J.B., Richert N.J. — Advanced Engineering Mathematicas with MATLAB | 193, 338 |
| Seitz F. — The Physics of Metals | 236 |
| Lee T.H. — Design of CMOS Radio-Frequency Integrated Circuits | 247 |
| Michalski L., Eckersdorf K., Kucharski J. — Temperature measurement | 128, 194 |
| Peebbles P.Z. — Radar Principles | 166 |
| Ugarov V.A. — Special Theory of Relativity | 278 |
| Hugh D. Young, Roger A. Freedman — University physics with modern physics | 977, 1311—1312, 1323, 1350—1351 |
| Lane S.M. — Mathematics, form and function | 304 |
| Beard D.B. — Quantum Mechanics | 10, 11 |
| Matt Young — Optics and Lasers: Including Fibers and Optical Waveguides | 4.2.1 |
| Hobbie R., Roth B. — Intermediate Physics for Medicine and Biology, | 244, 360 |
| Planck M. — Scientific Autobiography And Other Papers | 43—44 |
| 0 — Holt Physics | 727, 745, 876—877, 895 |
| HarrisR. — Nonclassical physics: beyond Newton's view | 72, 119, 198 |
| Taylor E.F. — Exploring Black Holes: Introduction to General Relativity | 5-34 |
| Schutz B.F. — A first course in general relativity | 52, 266, 309 |
| Blum E.K., Lototsky S.V. — Mathematics of Physics and Engineering | 348, 359 |
| Hademenos G.J. — Applied physics | 133—134 |
| Ashby N., Miller S.C. — Principles of modern physics | 111, 113, 115, 131, 504 |
| Miller W. — Symmetry and Separation of Variables | 73 |
| Synge J.L. — Relativity: The Special Theory | 154, 173, 182, 375 |
| Bates D.R. — Quantum Theory. I. Elements | 3 |
| Bluman G.W. — Similarity Methods for Differential Equations | 124 |
| Schiff L.I. — Quantum Mechanics | 2, 8 |
| Adler S.L. — Quaternionic Quantum Mechanics and Quantum Fields | 530, see also "Microscopic units" |
| Saha M.N., Srivastava B.N. — A treatise on heat: Including kinetic theory of gasses, thermodynamics and recent advances in statistical thermodynamics | 646 |
| Derbyshire J. — Prime Obsession: Bernhard Riemann and the greatest unsolved problem in mathematics | 316 |
| Greiner W. — Classical mechanics. Systems of particles and hamiltonian dynamics | 411 |
| Williams C.P., Clearwater S.H. — Explorations in quantum computing | 84, 260 |
| Haile J.M. — Molecular Dyanmics Simualtion: Elementary Methods | 462 |
| Haile J.M. — Molecular Dyanmics Simualtion: Elementary Methods | 462 |
| Binder K., Heermann D.W. — Monte Carlo Simulation in Statistical Physics | 146 |
| Hume-Rothery W. — Electrons, Atoms, Metals and Alloys | 26, 38, 46, 226 |
| Attwood S.S. — Electric and Magnetic Fields | 13, 256, 461 |
| Rice F.O., Teller E. — The structure of matter | 2, 3 |
| Prikarpatsky A.K., Taneri U., Bogolubov N.N. — Quantum field theory with application to quantum nonlinear optics | 5 |
| Lienhardt J.H. IV, Lienhardt J.H. V — A heat transfer textbook | 31 |
| Lyons L. — All You Wanted to Know about Mathematics but Were Afraid to Ask - Mathematics for Science Students. Volume 1 | 125—128, 294 |
| Slater J., Frank N. — Introduction to Theoretical Physics | 330 |
| Akenine-Möller T. — Real-Time Rendering | 184 |
| Close F. — The New Cosmic Onion: Quarks and the Nature of the Universe | 26 |
| Feynman R., Leighton R., Sands M. — Lectures on Physics 2 | I-5-10, I-6-10, I-17-8, I-37-11 |
| Landau L.D., Lifshitz E.M. — Course of Theoretical Physics (vol.3). Quantum Mechanics. Non-relativistic Theory | 20 |
| Davies P. — The New Physics | 71, 232, 426, 447 |
| Ehrenberg W. — Electric Conduction in Semiconductors and Metals | 35 |
| Mackey G. — Unitary Group Representations in Physics, Probability and Number Theory | 170, 210, 294 |
| Askeland D.R. — The Science and Engineering of Materials | 697 |
| Tipler F.J. — The Physics of Immortality | 100 |
| Guillemin V., Sternberg S. — Symplectic techniques in physics | 130 |
| Stamatescu I., Seiler E. — Approaches to Fundamental Physics | 399, 412 |
| Mac Lane S. — Mathematics: Form and Function | 304 |
| Melissinos A.C. — Principles of modern technology | 152 |
| Halpern A., Erlbach E. — Beginning Physics II: Waves, Electromagnetism, Optics and Modern Physics | 453 |
| Kittel C., Knight W., Ruderman M. — Berkeley physics course 1. Mechanics | 300, 366 |
| Rees M.J. — Just Six Numbers: The Deep Forces That Shape the Universe | 141 |
| Aharonov Y., Rohrlich D. — Quantum Paradoxes: Quantum Theory for the Perplexed | 1, 12, 14 |
| Ferziger J.H., Kaper H.G. — Mathematical theory of transport processes in gases | 259, 260, 331 |
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