| Êíèãà | Ñòðàíèöû äëÿ ïîèñêà |
| Wolf E.L. — Nanophysics and nanotechnology. An introduction to modern concepts in nanoscience | |
| Carey F.A. — Organic Chemistry | 520 |
| Chung T.J. — Computational fluid dynamics | 955 |
| Demtroeder W. — Laser spectroscopy | 166 |
| Pesic P. — Abel's Proof: An Essay on the Sources and Meaning of Mathematical Unsolvability | 140, 142, 196n |
| Naber G.L. — The geometry of Minkowski spacetime: an introduction to the mathematics of the special theory of relativity | 3 |
| Guenther R.D. — Modern optics | 1, 29—30 |
| Hand L.N., Finch J.D. — Analytical Mechanics | 494 |
| Lynch S. — Dynamical Systems with Applications Using Mathematica® | 308 |
| Monk P. — Finite Element Methods for Maxwell's Equations | 5 |
| Serre D. — Handbook of Mathematical Fluid Dynamics, Vol. 1 | 57 |
| Coffin D. — Calculus on the HP-48G/GX | 119 |
| Strauss W.A. — Partial Differential Equations: An Introduction | 39, 216—223, 230, 339 |
| Besse A.L. — Einstein Manifolds | 94 |
| Zel'dovich Ya.B., Raizer Yu.P. — Physics of Shock Waves and High-Temperature Hydrodynamic Phenomena (vol. 1) | 441 |
| Lerner K.L., Lerner B.W. — The gale encyclopedia of science (Vol. 6) | 1:6,1:12, 3:2159, 5:3408. See also Mass-energy relation (Einstein); Special relativity |
| Waseda Y. — Novel Application of Anomalous (Resonance) X-Ray Scattering for Structural Characterization of Disordered Materials | 6, 35, 44 |
| Huey E.G. — What makes the wheels go round? A first-time physics | 135 |
| Jahne B. — Digital Image Processing | 147 |
| Fishbane P.M. — Physics For Scientists and Engineers with Modern Physics | 943, 948, 966, 975—977 |
| Young M. — Optics and Lasers: Including Fibers and Optical Waveguides | 5.1.1, see also “Velocity of light” |
| Fulling S. — Aspects of Quantum Field Theory in Curved Spacetime | 162 |
| Billingham J., King A.C. — Wave Motion | 182, 195 |
| Feynman R.P., Leighton R.B., Sands M. — The Feynman lectures on physics (vol.2) | I-15-1, II-18-8 f |
| Lopuzanski J. — An introduction to symmetry and supersymmetry in quantum field theory | 2 |
| O'Neill B. — Semi-Riemannian Geometry: With Applications to Relativity | 161—162 |
| Kunz K.S., Luebbers R.J. — The finite difference time domain method for electromagnetics | 219 |
| Nayfeh M.H., Brussel M.K. — Electricity and Magnetism | 30, 443 |
| Mishchenko M.I. — Scattering, Absorption, and Emission of Light by Small Particles | 14 |
| Zel'dovich Ya.B., Raizer Yu.P. — Physics of Shock Waves and High-Temperature Hydrodynamic Phenomena (vol. 2) | 441, 881 |
| Englert B.G. (Ed) — Quantum Mechanics | 183, 191, 321 |
| Lang K.R. — Astrophysical Formulae: Space, Time, Matter and Cosmology, Vol. 2 | 26, 149 |
| Wolf E.L. — Nanophysics and nanotechnology: an introduction to modern concepts in nanoscience | 10, 55 |
| Sernelius B.E. — Surface Modes in Physics | 44 |
| Mason G.W., Griffen D.T., Merrill J. — Physical Science Concepts | 43, 75-77, 79-85, 123-124, 129-131, 225, 246-247, 359, 363-364, 369, 380 |
| Junker G. — Supersymmetric Methods in Quantum and Statistical Physics | 9 |
| Carrol B.W., Ostlie D.A. — An introduction to modern astrophysics | 63, 87 |
| Greiner W. — Classical electrodynamics | 313 |
| O'Neill B. — The Geometry of Kerr Black Holes | 38—40 |
| D'Inverno R. — Introducing Einstein's Relatvity | see light |
| Dewdney A.K. — Beyond reason. 8 great problems that reveal the limits of science | 35—57, 60 |
| Stewart I.W. — The Static and Dynamic Continuum Theory of Liquid Crystals: A Mathematical Introduction | 329 |
| Demtröder W. — Laser spectroscopy: basic concepts and instrumentation | 166 |
| Weinberg S. — Gravitation and Cosmology: Principles and Applications of the General Theory of Relativity | (see Light speed) |
| Bakst A. — Mathematics. Its Magic and Mystery | 71, 73 |
| Greene B. — The elegant univerce | (see Light, speed of) |
| Vincenti W.G., Kruger C.H. — Introduction to Physical Gas Dynamics | 524 |
| Anisimov S.I., Khokhlov V.A. — Instabilities in Laser-matter interaction | 19 |
| Ohanian H.C. — Classical Electrodynamics | 158, 159, 160, 165, 523 |
| Peebbles P.Z. — Radar Principles | 2n |
| Rogers L. — Its ONLY Rocket Science. An Introduction in Plain English (Astronomers Universe) | 10, 220, 237, 289 |
| McQuarrie D.A. — Statistical Mechanics | 593 |
| Hugh D. Young, Roger A. Freedman — University physics with modern physics | 5, 1095—1101, 1121, 1269—1270 |
| Lauterborn W., Kurz T. — Coherent optics | 1, 2, 5, 15, 73, 137, 277 |
| Lauterborn W., Kurz T. — Coherent optics | 1, 2, 5, 15, 73, 137, 277 |
| Matt Young — Optics and Lasers: Including Fibers and Optical Waveguides | 5.1.1, see also "Velocity of light" |
| Crew H. — THE WAVE THEORY OF LIGHT MEMOIRS OF HUYGENS YOUNG AND FRESNEL | 13 |
| Blum E.K., Lototsky S.V. — Mathematics of Physics and Engineering | 98, 164, 348 |
| Ashby N., Miller S.C. — Principles of modern physics | 43, 504 |
| Adams S. — Relativity: An Introduction to Space-Time Physics | 19, 22, 75, 120, 140, 159, 248 |
| Synge J.L. — Relativity: The Special Theory | 54, 55, 182, 183, 352, 385 |
| Jahne B., Haubecker H. — Computer vision and applications | 13 |
| Rice J.A. — Mathematical statistics and data analysis | 128 |
| Thorne K.S., Hawking S. — Black holes and time warps: Einstein's outrageous legacy | see also "Absoluteness of speed of light" |
| Close F. — The New Cosmic Onion: Quarks and the Nature of the Universe | 17 |
| Shu-Ang Zhou — Electrodynamics of solids and microwave superconductivity | 19 |
| Cercignani C. — Rarefied Gas Dynamics | 225 |
| Feynman R., Leighton R., Sands M. — Lectures on Physics 2 | I-15-1, II-18-8 f |
| Davies P. — The New Physics | 426, 447, 459, 477 |
| Yao W-M — Review of particle physics | 98 |
| Blin-Stoyle R.J. — Eureka! Physics of particles, matter and the universe | 58 |
| Stamatescu I., Seiler E. — Approaches to Fundamental Physics | 97 |
| Halpern A., Erlbach E. — Beginning Physics II: Waves, Electromagnetism, Optics and Modern Physics | 317 |
| Rees M.J. — Just Six Numbers: The Deep Forces That Shape the Universe | 32, 32, 33—34, 47, 60, 62 |
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