| Êíèãà | Ñòðàíèöû äëÿ ïîèñêà |
| Zinn-Justin J. — Quantum field theory and critical phenomena | 431 |
| Donaldson K., Kronheimer P.B. — Geometry of Four-Manifolds | 55, 57, 167 |
| Vilenkin A., Shellard E.P.S. — Cosmic strings and other topological defects | 127, 231 |
| Liboff R. — Kinetic Theory | 464 |
| Jensen F. — Introduction to Computational Chemistry | 249 |
| Atkins P.W., Friedman R.S. — Molecular Quantum Mechanics | 442 |
| Hess B.A. — Relativistic Effects in Heavy-Element Chemistry and Physics | 129 |
| Mukamel S. — Principles of Nonlinear Optical Spectroscopy | 80 |
| Fradkin E. — Field theories of condensed matter systems | 215 |
| Greiner W. — Quantum mechanics. An introduction | 14, 206 |
| Thaller B. — Visual quantum mechanics | 99 |
| Kapusta J.I. — Finite-temperature field theory | 89, 95, 97, 128, 133, 144, 152 |
| Getzlaff M. — Fundamentals of Magnetism | 7 |
| Pokorski S. — Gauge field theories | 132 |
| Ziman J.M. — Elements of Advanced Quantum Theory | 182 |
| Ramond P. — Field Theory: A Modern Primer | 284 |
| Mukamel S. — Principles of nonlinear spectroscopy | 80 |
| Konopinski E.J. — Electromagnetic fields and relativistic particles | see Gauge, solenoidal (transverse, Coulomb) |
| Frampton P. — Dual Resonance Models and Superstrings | 142, 143, 157 |
| Thaller B. — The Dirac equation | 245 |
| Ramond P. — Field Theory: A modern Primer | 227 |
| Yamamoto Y., Imamoglu A. — Mesoscopic quantum optics | 35 |
| Nagaosa N. — Quantum field theory in condensed matter physics | 25 |
| De Gennes P.G., Prost J. — The Physics of Liquid Crystals | 513 |
| Meschede D. — Optics, Light and Lasers: The Practical Approach to Modern Aspects of Photonics and Laser Physics | 34 |
| Greiner W., Muller B. — Gauge theory of weak interactions | 133 |
| Dekker H. — Classical and quantum mechanics of the damped harmonic oscillator | 65 |
| Nayfeh M.H., Brussel M.K. — Electricity and Magnetism | 258, 470 |
| Gardiner C.W., Zoller P. — Quantum Noise: A Handbook of Markovian and Non-Markovian Quantum Stochastic Methods with Applications to Quantum Optics | 231 |
| Dutra S.M. — Cavity quantum electrodynamics | 157 |
| Mandl F., Shaw G. — Quantum field theory | 3 |
| Rivers R.J. — Path Integral Methods in Quantum Field Theory | 202, 207 |
| Collins P.D., Squires E.J., Martin A.D. — Particle Physics and Cosmology | 34 |
| Jackson J.D. — Classical electrodynamics | 181 |
| Weinberg S. — The Quantum Theory of Fields. Vol. 1 Foundations | 251, 346—50, 365 |
| Griffits D. — Introduction to elementary particles | 227—229, 281, 302 |
| Cohen-Tannoudji C., Dupont-Roc J., Grynberg G. — Photons and atoms: introduction to quantum electrodynamic | (see also “Hamiltonian (total)”, “Lagrangians for electrodynamics”) |
| Bjorken J.D., Drell S.D. — Relativistic Quantum Fields | 86 |
| Collins P.D.B., Martin A.D., Squires E.J. — Particle Physics and Cosmology | 34 |
| Greiner W., Reinhardt J. — Quantum electrodynamics | 35, 227ff., 266, 369 |
| Araki H. (ed.), Ezawa H. (ed.) — Topics in the Theory of Schrödinger Operators | 154 |
| Greiner W. — Classical electrodynamics | 205, 410 |
| Greiner W. — Quantum mechanics: special chapters | 3, 4, 32 |
| Halzen F., Martin A.D. — Quarks and Leptons: An Introductory Course in Modern Particle Physics | 1, 14 |
| Davies B. — Integral Transforms and Their Applications | 187 |
| Neff H.P.Jr. — Introductory electromagnetics | 88 |
| Scully M.O., Zubairy M.S. — Quantum optics | 40 |
| Stahl A., Balslev I. — Electrodynamics of the Semiconductor Band Edge | 174 |
| McQuistan R.B. — Scalar and Vector Fields: a Physical Interpretation | 296 |
| Perina J., Hradil Z., Jurco B. — Quantum optics and fundamentals of physics | 29 |
| Fox M. — Optical properties of solids | 257, 267 |
| Gardiner C.W. — Quantum Noise | 233 |
| Nouredine Z. — Quantum Mechanics: Concepts and Applications | 348, 564, 565 |
| Novikov S.P., Fomenko A.T. — Basic elements of differential geometry and topology | 379 |
| Mandel L., Wolf E. — Optical Coherence and Quantum Optics | 466, 687 |
| Weinberg S. — The Quantum Theory of Fields. Vol. 2 Modern Applications | 15 |
| Ram-Mohan R. — Finite Element and Boundary Element Applications in Quantum Mechanics | 171 |
| Greiner W., Reinhardt J. — Field quantization | 144—145, 171, 196, 197, 208, 319 |
| Richards P.I. — Manual of Mathematical Physics | 67 |
| Rosser G. — Interpretation of classical electromagnetism | 84—88, 146 |
| Thaller B. — The Dirac equation | 245 |
| Atkins P.W., Friedman R.S. — Molecular Quantum Mechanics | 417 |
| Leader E., Predazzi E. — An introduction to gauge theories and modern particle physics | 2.102 |
| Milonni P.W. — The quantum vacuum: introduction to quantum electrodynamics | 39, 47, 120, 291, 361—364 |
| Griffits D.J. — Introductions to electrodynamics | 421, 541 |
| Moriyasu K. — An Elementary Primer for Gauge Theory | 41 |
| Anderson J.L. — Principles of Relativity Physics | 287 |
| Greiner W. — Relativistic quantum mechanics. Wave equations | 51 |
| Barut A.O. — Electrodynamics and Classical Theory of Fields and Particles | 95 |
| Ticciati R. — Quantum field theory for mathematicians | 259 |
| Breuer H.-P., Petruccione F. — The Theory of Open Quantum Systems | 391, 569 |
| Powell R. — Physics of Solid State Laser Materials (Atomic, Molecular and Optical Physics Series) | 85, 88 |
| Greiner W., Maruhn J. — Nuclear models | 75 |
| Kleinert H. — Gauge fields in condensed matter (part 2) | 284 |
| Kane G.L. — Modern elementary particle physics | 41 |
| Collins P.D.B., Martin A.D., Squires E.J. — Particle Physics and Cosmology | 34 |
| Azcarraga J., Izquierdo J. — Lie groups, Lie algebras, cohomology and some applications in physics | 361 |
| Perina J., Hradil Z., Jurco B. — Quantum optics and fundamentals of physics | 29 |
| Bellac M. — Thermal Field Theory (Cambridge Monographs on Mathematical Physics) | 104, 147, 169, 223, 240 |
| Davies B. — Integral Transforms and their Applications | 187 |
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