| Êíèãà | Ñòðàíèöû äëÿ ïîèñêà |
| Wolf E.L. — Nanophysics and nanotechnology. An introduction to modern concepts in nanoscience | |
| Greenwood N.N., Earnshaw A. — Chemistry of the Elements | see also “Spin equilibria” |
| Enns R.H., Mc Guire G.C. — Nonlinear physics with mathematica for scientists and engineers | 620, 646 |
| Goldstein H., Poole C., Safko J. — Classical mechanics | 230 |
| Wesson J. — Tokamaks | 49 |
| Dill K.A., Bromberg S. — Molecular Driving Forces: Statistical Thermodynamics in Chemistry and Biology | 187 |
| Marmo G., Skagerstam B.S., Stern A. — Classical topology and quantum states | 17, 230, 238, 242 |
| Von Laue M. — History of Physics | 45 |
| Honerkamp J. — Statistical Physics | 125 |
| Greiner W. — Quantum mechanics. An introduction | 5, 229, 329, 363 |
| Wyld H.W. — Mathematical Methods for Physics | 240 |
| Getzlaff M. — Fundamentals of Magnetism | 1 |
| Mihaly L., Martin M.C. — Solid state physics. Problems and solutions | 97, 237 |
| Ziman J.M. — Elements of Advanced Quantum Theory | 101 |
| Toda M., Kubo R., Saito N. — Statistical Physics I: Equilibrium Statistical Mechanics, Vol. 1 | 11 |
| Galindo A., Pascual P. — Quantum Mechanics Two | I 19, 249, 295, II 214 |
| Planck M. — Theory of electricity and magnetism,: Being volume III of Introduction to theoretical physics | 93 |
| Menzel D.H. — Mathematical Physics | 13 |
| Eddington A. — Relativity Theory of Protons and Electrons | 88, 89 |
| Konopinski E.J. — Electromagnetic fields and relativistic particles | see Magnetic dipole moment |
| Guimaraes A.P. — Magnetism and Magnetic Resonance in Solids | 2—3, 25, 27—28, 32, 60, 69—70, 75—76, 91—92, 96, 98, 107, 122, 132, 134, 151, 153—154, 165, 167, 171, 175, 178, 181, 191—193, 210, 213—214, 217, 227, 229—230, 238—239, 242, 248, 259, 263 |
| Kyle T.G. — Atmospheric transmission, emission and scattering | 158 |
| Lamb C.G. — Notes on Magnetism | 6 |
| Brillouin L. — Wave Propagation in Periodic Structures | 236 |
| Heitler W. — Elementary Wave Mechanics With Applications to Quantum Chemistry | 55, 60 |
| Stanley H.E. — Introduction to phase transitions, and critical phenomena | 4, 16 |
| Rickayzen G. — Green's functions and condensed matter | 344 |
| Atkinson D., Johnson P.W. — Exercises in Quantum Field Theory: A Self-Contained Book of Questions and Answers | 34 |
| Peleg Y., Pnini R., Zaarur E. — Schaum's outline of theory and problems of quantum mechanics | 155 |
| Nayfeh M.H., Brussel M.K. — Electricity and Magnetism | 274 |
| Kubo R. — Statistical Mechanics: An Advanced Course with Problems and Solutions | 133, 263, 304 |
| O'Raifeartaigh L. — Group Structure of Gauge Theories | 68 |
| Castelfranchi G. — Recent Advances in Atomic Physics | ii, 229 |
| Galindo A., Pascual P. — Quantum Mechanics One | 19, 249, 295 |
| Englert B.G. (Ed) — Quantum Mechanics | 29, 30, 38, 69, 387 (see also “Magnetic dipole”) |
| Meyerhof W.E. — Elements of Nuclear Physics | 52, 122n |
| Lichtenberg A.J., Liebermen M.A. — Regular and Chaotic Dynamics | 88, 99—100, 648—649 |
| Auerbach F. — Modern magnetics | 22, 35 |
| Collins P.D., Squires E.J., Martin A.D. — Particle Physics and Cosmology | 48, 122 |
| Griffits D. — Introduction to elementary particles | 153 |
| Wolf E.L. — Nanophysics and nanotechnology: an introduction to modern concepts in nanoscience | 70 |
| Animalu A.O. — Intermediate Quantum Theory of Crystalline Solids | 34 |
| Stratton J.A. — Electromagnetic Theory | 229 |
| Kivelson Margaret G., Russell Christopher T. — Introduction to Space Physics (Cambridge Atmospheric & Space Science Series) | 33, 165—168, 308 |
| Collins P.D.B., Martin A.D., Squires E.J. — Particle Physics and Cosmology | 48, 122 |
| Greiner W. — Classical electrodynamics | 181, 213, 219 |
| Economou E.N. — Green's Functions in Quantum Physics | 329, 331 |
| Halzen F., Martin A.D. — Quarks and Leptons: An Introductory Course in Modern Particle Physics | 107, 119 |
| Shankar R. — Principles of quantum mechanics | 385 |
| Bardin D., Passarino G. — The Standard Model in the Making: Precision Study of the Electroweak Interactions | 11 |
| Rose M.E. — Relativistic Electron Theory | 2, 76, 78, 122, 129, 189, 270 |
| Gilmore R. — Lie Groups, Lie Algebras and Some of Their Applications | 162 |
| Houston W.V. — Principles of Mathematical Physics | 216 |
| Siegel W. — Fields | IIIC4, VIIA3, VIIIB5 |
| Peddie W. — Molecular Magnetism | 6 |
| Cotterill R.M.J. — Biophysics: An Introduction | 95 |
| Basdevant J.-L., Dalibard J. — Quantum Mechanics | 157, 201 |
| Grosche C., Steiner F. — Handbook of Feynman path integrals | 17 |
| Fernow R.C. — Introduction to experimental particle physics | 10, 362—4 |
| Cramer N.F. — The Physics of Alfvén Waves | 46 |
| Rossnagel S.M., Cuomo J.J., Westwood W.D. — Handbook of plasma processing technology. Fundamentals, etching, deposition, and surface interaction | 27 |
| Ashcroft N.W., Mermin N.D. — Solid State Physics | see also "Susceptibility" |
| Tauxe L. — Paleomagnetic principles and practice | 5, 39, 58 |
| Richter K. — Semiclassical theory of mesoscopic quantum systems | 83 |
| Landau L.D., Lifshitz E.M. — The classical theory of fields | 111 |
| Thomas A.W., Weise W. — The structure of the nucleon | 245 |
| Ohanian H.C. — Classical Electrodynamics | 273, 274, 337 |
| Messiah A. — Quantum mechanics. Volume 1 | 25 |
| Frenkel J. — Wave Mechanics: Advanced General Theory | 256, 275, 280 |
| Wigner E.P. — Group Theory and Its Applicaion to the Quantum Mechanics of Atomic Spectra | 220 |
| Umezawa H. — Quantum Field Theory | 111, 112, 117, 177 |
| Stratton J.A. — Electromagnetic Theory | 229 |
| Povh B., Rith K., Scholz C., Zetsche F. — Particles and nuclei. An introduction to the Physical Concepts | 74 |
| Roepstorf G. — Path integral approach to quantum physics | 206 |
| Bohr A., Mottelson B.R. — Nuclear Structure (Vol. 1): Single-Particle Motion | see "M1 moment" |
| Haar D. — Selected problems in quantum mechanics | 4.30—4.32 |
| Bornemann F. — Homogenization in Time of Singularly Perturbed Mechanical Systems (Lecture Notes in Mathematics, 1687) | 76 |
| Siegel W. — Fields | IIIC4, VIIA3, VIIIB5 |
| Biskamp D. — Magnetic Reconnection in Plasmas | 118, 299 |
| Wolfgang K. H. Panofsky, Phillips Panofsky, Melba Panofsky — Classical Electricity and Magnetism | 130, 261, 334, 437 |
| Brewer D.F. — Progress in Low Temperature Physics. Volume X | 24, 27, 156, 160 |
| Mohapatra R.N. — Massive Neutrinos in Physics and Astrophysics | 260 |
| Hobbie R., Roth B. — Intermediate Physics for Medicine and Biology, | 204, 516 |
| Mandl F. — Quantum mechanics | 47, 111—112 |
| Hoyer U. — Work on Atomic Physics (1912 - 1917) | 96, 99, 128—130, 233, 377, 424 |
| Ashby N., Miller S.C. — Principles of modern physics | 236, 413 |
| Greiner W. — Relativistic quantum mechanics. Wave equations | 254 |
| Freidberg J.P. — Plasma Physics and Fusion Energy | see "Adiabatic invariant" |
| Barut A.O. — Electrodynamics and Classical Theory of Fields and Particles | 73 |
| Kubo R. — Thermodynamics | 34 |
| Spitzer L.Jr. — Physics of Fully Ionized Gases Interscience Tracts on Physics and Astronomy No. 3 | 7—11, 13, 14, 57 |
| Brown L., Dresden M., Hoddeson L. — Pions to quarks: Particle physics in the 1950s | 10, 19, 27, 133, 140, 144, 486 |
| Hoselitz K. — Ferromagnetic Properties of Metals and Alloys | 2 |
| Kravens T.E. — Physic of Solar System Plasmas | 47—49, 56, 58 |
| Attwood S.S. — Electric and Magnetic Fields | 217, 252, 375, 383 |
| Rice F.O., Teller E. — The structure of matter | 183, 184, 300 |
| Hickman M. (Ed), Mirchandani P. (Ed) — Computer-Aided Systems in Public Transport | 6, 229—231 |
| Dolan T.J. — Fusion Research: Principles, Experiments and Technology | 158 |
| Kirk J., Melrose D., Priest E. — Plasma astrophysics | 159, 231 |
| Sturrock P. — Plasma Physics: An Introduction to the Theory of Astrophysical, Geophysical and Laboratory Plasmas | 27, 37, 47, 54 |
| Greiner W., Maruhn J. — Nuclear models | 177 |
| Davies P. — The New Physics | 210—211, 214, 217, 406—407 |
| Askeland D.R. — The Science and Engineering of Materials | 672, 694 |
| Collins P.D.B., Martin A.D., Squires E.J. — Particle Physics and Cosmology | 48, 122 |
| Castelfranchi C. — Recent advances in Atomic Physics Volume II Quantum Theory | ii.229 |
| Ichimaru S. — Statistical Plasma Physics, Volume I: Basic Principles (Frontiers in Physics, Vol 87) (v. 1) | 190 |
| Jackson J.D. — Classical electrodynamics | see also "Dipole moment" |
| Krall N., Trivelpiece A. — Principles of Plasma Physics | 627 |
| Lilley J.S. — Nuclear physics: principles and applications | 6 |
| Honerkamp J. — Statistical physics: an advanced approach with applications | 125 |
| Helander P., Sigmar D.J. — Collisional Transport in Magnetized Plasmas | 101 |
| Liboff R.L. — Introductory quantum mechanics | 457 |
| Bell J., Kearsley M., Pitaevskii L. — Course of Theoretical Physics, Volume 8, Volume 8, Second Edition: Electrodynamics of Continuous Media | 106 |
| Landau L.D., Lifshitz E.M. — Course of Theoretical Physics, Volume 8: Electrodynamics of Continuous Media | 106 |
| Bell J.S., Kearsley M.J. — Course of Theoretical Physics, Volume 8: Electrodynamics of Continuous Media | 106 |
| L.D. Landau, E.M. Lifshitz — Electrodynamics of Continuous Media | 106 |
| L.D. Landau — Electrodynamics of Continuous Media | 106 |
| L. D. LANDAU, E. M. LIFSHITZ — ELECTRODYNAMICS OF CONTINUOUS MEDIA | 106 |
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