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Ïîèñê êíèã, ñîäåðæàùèõ: dispersion relation
| Êíèãà | Ñòðàíèöû äëÿ ïîèñêà | | Wolf E.L. — Nanophysics and nanotechnology. An introduction to modern concepts in nanoscience | | | Gomez C., Ruiz-Altaba M., Sierra G. — Quantum Groups in Two-Dimensional Physics | 71, 72, 83, 300 | | Zeidler E. — Nonlinear Functional Analysis and its Applications IV: Applications to Mathematical Physic | 100, 102, 449 | | Di Francesco P., Mathieu P., Senechal D. — Conformal field theory | 19, 23 | | Felsager B. — Geometry, particles and fields | 84, 90 | | Zienkiewicz O.C., Taylor L.R. — The finite element method (vol. 3, Fluid dynamics) | 243, 269, 271 | | Kevorkian J., Cole J.D. — Multiple Scale and Singular Perturbation Methods | 524, 532 | | Hinch E.J. — Perturbation Methods | 138 | | Kundu P.K., Cohen I.R. — Fluid mechanics | 203, 605—606, 610—613 | | Nayfeh A.H., Mook D.T. — Nonlinear Oscillations | 544, 545, 585, 586, 596, 615 | | Drazin P. — Introduction to Hydrodynamic Stability | 70, 73, 85, 86, 200 | | Parisi G. — Statistical field theory | 261 | | Pedlosky J. — Waves in the ocean and atmosphere: introduction to wave dynamics | 7, 13, 17, 27, 33, 43, 50, 63, 64, 67, 83, 113, 138, 190, 203, 209 | | Wesson J. — Tokamaks | 94 | | Biscamp D. — Magnetohydrodynamic turbulence | 28 | | Stauffer D., Aharony A. — Introduction To Percolation Theory | 125 | | Debnath L., Mikusinski P. — Introduction to Hilbert Spaces with Applications | 368 | | Debnath L. — Nonlinear Partial Differential Equations for Scientists and Engineers | 264, 278, 407, 441, 443—444, 446, 497, 516 | | Kuchment P. — Floquet theory for partial defferential equations | 152 | | Safran S.A. — Statistical thermodynamics on surfaces, interfaces and membranes | 89, 148, 173 | | Gracia-Bondia J.M., Varilly J.C., Figueroa H. — Elements of Noncommutative Geometry | 589 | | Maurel A., Petitjeans P. — Vortex Structure and Dynamics | 77 | | Debnath L. — Linear Partial Differential Equations for Scientists and Engineers | 541, 573 | | Tompkins H.G., Irene E.A. — Handbook of Ellipsometry | 135, 739, 741, 795 | | Ablowitz M.J., Fokas A.S. — Complex Variables: Introduction and Applications | 295, 475 | | Thaller B. — Visual quantum mechanics | 50 | | Kapusta J.I. — Finite-temperature field theory | 7, 95, 101, 104, 109 (see also “Collective excitations”, “Plasma oscillations”) | | Itoh K., Fukayama A. — Transport and Structural Formation in Plasmas | 57—58 | | Zakharov V.E. — What is integrability? | 23 | | Wyld H.W. — Mathematical Methods for Physics | 481—492 | | Friedlander S.J. (Ed), Serre D. (Ed) — Handbook of Mathematical Fluid Dynamics, Vol. 3 | 356 | | Mills D.L. — Nonlinear optics | 18 | | Getzlaff M. — Fundamentals of Magnetism | 83 | | Walecka J.D. — Fundamentals of statistical mechanics | 137, 215 | | Mihaly L., Martin M.C. — Solid state physics. Problems and solutions | 22, 134 | | Dorlas T.C. — Statistical mechanics, fundamentals and model solutions | 196 | | Griffits D.J. — Introduction to quantum mechanics | 47 | | Stauffer D., Aharony A. — Introduction to percolation theory | 125 | | Domb C., Lebowitz J.L. — Phase Transitions and Critical Phenomena (Vol. 19) | 67, 115 | | Brown L.S. — Quantum Field Theory | 170, 455 | | Pettifor D.G. — Bonding and structure of molecules and solids | 29 | | Waseda Y. — Novel Application of Anomalous (Resonance) X-Ray Scattering for Structural Characterization of Disordered Materials | 27, 34, 46, 98 | | Zajac A. — Optics | 298 | | Ablowitz M.J., Segur H. — Solitons and the Inverse Scattering Transform | 31, 45, 46—49, 61—64, 66, 68, 74—78, 88, 119, 122, 129, 130, 131, 152, 156, 157, 170, 179, 261, 278, 286, 293, 300—304, 307, 308, 311, 314, 335, 352—355, 358, 362, 363, 367, 370, 373—376, 381—386, 389 | | Guimaraes A.P. — Magnetism and Magnetic Resonance in Solids | 84, 89, 93 | | Zauderer E. — Partial Differential Equations of Applied Mathematics | 144, 630, 645, 774 | | Cleland A.N. — Foundations of nanomechanics | 19 | | Sakai K. (ed.) — Terahertz Optoelectronics | 215, 218, 223, 225 | | Hilborn R.C. — Chaos and nonlinear dynamics | 465 | | Ohayo R. — Structural acoustics and vibration: mechanical models, variational formulations and discretization | 183 | | Banerjee P.P., Poon T.-C. — Principles of applied optics | 4, 77, 295, 330 | | Kubo R., Toda M., Hashitsume N. — Statistical physics II. Nonequilibrium statistical mechanics | 34, 138, 166, 182, 207 | | Billingham J., King A.C. — Wave Motion | 10, 15, 77, 79, 84, 88, 93, 96, 99, 100, 111, 121, 146, 148, 156, 286, 295, 304 | | Povey M.J. — Ultrasonic Techniques for Fluids Characterization | 108, 153 | | Landau L.D., Lifschitz E.M. — Fluid Mechanics. Vol. 6 | 33 | | Landau L.D., Lifschitz E.M. — Statistical physics (vol. 9 of course of theoretical physics) | 142 | | Stone M. — The physics of quantum fields | 66 | | Kulish V.V. — Hierarchical Methods: Hierarchy and Hierarchical Asymptotic Methods In Electrodynamics, Volume 1 | 27, 109, 278 | | Kittel Charles, Kroemer Herbert — Thermal Physics | 425 | | Lim Y. (ed.) — Problems and solutions on electromagnetism. (Major American Universities Ph.D. Qualifying Questions and Solutions) | 4028, 5046, 5049, 5051, 5052 | | Cercignani C. — Theory and Application of the Boltzman Equation | 201, 330, 333, 335, 336 | | Betchov R. — Stability of Parallel Flows | 241, 244 | | Elze H.-T. (ed.) — Decoherence and entropy in complex systems | 98 | | Gruener G. — Density waves in solids | 140, 141 | | Wolf E.L. — Nanophysics and nanotechnology: an introduction to modern concepts in nanoscience | 19 | | Kleinert H., Schulte-Frohlinde — Critical Properties of (Phi)P4-Theories | 285 | | Lynch D.R. — Numerical Partial Differential Equations for Environmental Scientists and Engineers: A First Practical Course | 64, 99 | | Basdevant J.-L., Dalibard J. — The Quantum Mechanics Solver | 207 | | Greiner W., Reinhardt J. — Quantum electrodynamics | 190, 355, 356 | | Greiner W. — Quantum mechanics: special chapters | 207 | | Volovik G. — Artificial black holes | 50, 51, 65, 96, 102, 112, 117, 119, 122, 134, 185, 188-190, 196, 218, 219, 234, 359, 375 | | Estrada R., Kanwal R.P. — A distributional approach to asymptotics theory and applications | 212 | | Garbey M., Kaper H.G. — Asymptotic Analysis and the Numerical Solution of Partial Differential Equations, Vol. 130 | 257 | | Likharev K.K. — Dynamics of Josephson junctions and circuits | 530—31 | | Lim Y. (ed.) — Problems and solutions on solid state physics, relativity and miscellaneous topics | 1032, 1057 | | Cramer N.F. — The Physics of Alfvén Waves | 9 | | Mourachkine A. — High-Temperature Superconductivity in Cuprates: The Nonlinear Mechanism and Tunneling Measurements | 14 | | Cheng T.-P., Li L.-F. — Gauge Theory of Elementary Particle Physics | 159, 60, 301-2 | | Thomas A.W., Weise W. — The structure of the nucleon | 20, 37, 162 | | Jähne B. — Spatio-Temporal Image Processing | 116 | | Appenzeller I. (ed.), Habing H.J. (ed.), Léna P. (ed.) — Evolution of Galaxies Astronomical Observations | 44 | | Büchner J., Dum C., Scholer M. — Space Plasma Simulation | 39 | | Ugarov V.A. — Special Theory of Relativity | 248 | | Carroll R.W. — Mathematical physics | 209, 214 | | Tzenov S.I. — Contemporary Accelerator Physics | 258, 268 | | Saito Y. — Statistical physics of crystal growth | 62, 79, 82, 106 | | Wolfgang K. H. Panofsky, Phillips Panofsky, Melba Panofsky — Classical Electricity and Magnetism | 416, 419 | | Mohapatra R.N. — Massive Neutrinos in Physics and Astrophysics | 322—325, 327—329, 336, 338, 339 | | Gould H., Tobochnik J., Christian W. — An introduction to computer simulation methods | 315 | | Wiedemann H. — Particle accelerator physics II | 372, 374, 381, 382 | | Datta S. — Electronic transport in mesoscopic systems | 12, 32—37, 144, 277—278 | | Biskamp D. — Magnetohydrodynamic Turbulence | 28 | | Motz H., Luchini P. — Undulators and free-electron lasers | 8, 68, 83, 86—87, 141—145, 147—148, 153, 162, 167, 311 | | HarrisR. — Nonclassical physics: beyond Newton's view | 218, 221, 222 | | Amelino-Camelia G., Kowalski-Glikman J. — Planck Scale Effects in Astrophysics and Cosmology (Lecture Notes in Physics) | 184 | | Ashby N., Miller S.C. — Principles of modern physics | 6, 352 | | Henkel M. — Conformal Invariance and Critical Phenomena | 77, 163, 188, 196, 244, 380, 382 | | Tsang L., Kong J.A. — Scattering of electromagnetic waves (Vol 3. Advanced topics) | 212—214 | | Freidberg J.P. — Plasma Physics and Fusion Energy | see "Electromagnetic waves" | | Schiff L.I. — Quantum Mechanics | 344 | | Haag R. — Local quantum physics: fields, particles, algebras | 101 | | Zeidler E. — Oxford User's Guide to Mathematics | 534 | | Spitzer L.Jr. — Physics of Fully Ionized Gases Interscience Tracts on Physics and Astronomy No. 3 | 50, 53, 55, 56, 57, 59 | | Murray J.D. — Asymptotic Analysis | 80 | | Dolan T.J. — Fusion Research: Principles, Experiments and Technology | 124 | | Kirk J., Melrose D., Priest E. — Plasma astrophysics | see "Waves" | | Groesen E., Molenaar J. — Continuum Modeling in the Physical Sciences (Monographs on Mathematical Modeling and Computation) | 98 | | Sturrock P. — Plasma Physics: An Introduction to the Theory of Astrophysical, Geophysical and Laboratory Plasmas | 69, 79, 82, 83, 91, 123, 315 | | Cercignani C. — Rarefied Gas Dynamics | 137, 139, 140 | | Landau L.D., Lifshitz E.M. — Course of Theoretical Physics (vol.3). Quantum Mechanics. Non-relativistic Theory | 532—535 | | Guillemin V., Sternberg S. — Symplectic techniques in physics | 392 | | Ichimaru S. — Statistical Plasma Physics, Volume I: Basic Principles (Frontiers in Physics, Vol 87) (v. 1) | 75, 178 | | Landau L., Sykes J. — Fluid Mechanics: Vol 6 (Course of Theoretical Physics) | 33 | | Logan J. — Applied Mathematics: A Contemporary Approach | 245 | | Edwards D.A., Syphers M.J. — An introduction to the physics of high energy accelerators | 207—208, 210, 219 | | Constanda C. (ed.), Potapenko S.S. (ed.) — Integral Methods in Science and Engineering: Techniques and Applications | 104 | | Constanda C., Potapenko S. — Integral Methods in Science and Engineering: Techniques and Applications | 104 | | Constanda C. (ed.), Potapenko S. (ed.) — Integral methods in science and engineering | 104 | | Bell J., Kearsley M., Pitaevskii L. — Course of Theoretical Physics, Volume 8, Volume 8, Second Edition: Electrodynamics of Continuous Media | 236, 266 | | Landau L.D., Lifshitz E.M. — Course of Theoretical Physics, Volume 8: Electrodynamics of Continuous Media | 236, 266 | | Bell J.S., Kearsley M.J. — Course of Theoretical Physics, Volume 8: Electrodynamics of Continuous Media | 236, 266 | | L.D. Landau, E.M. Lifshitz — Electrodynamics of Continuous Media | 236, 266 | | L.D. Landau — Electrodynamics of Continuous Media | 236, 266 | | L. D. LANDAU, E. M. LIFSHITZ — ELECTRODYNAMICS OF CONTINUOUS MEDIA | 236, 266 |
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