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| Ðåçóëüòàò ïîèñêà |
Ïîèñê êíèã, ñîäåðæàùèõ: Propagator
| Êíèãà | Ñòðàíèöû äëÿ ïîèñêà | | Anderson P.W. — Basic notions of condensed matter physics | | | Schmalzried H. — Chemical Kinetics of Solids | 99 | | Gomez C., Ruiz-Altaba M., Sierra G. — Quantum Groups in Two-Dimensional Physics | 318, 328, 340 | | Zinn-Justin J. — Quantum field theory and critical phenomena | 95 | | Di Francesco P., Mathieu P., Senechal D. — Conformal field theory | 26 | | Zinn-Justin J. — Quantum field theory and critical phenomena | 86 | | Cvitanovic P. — Group theory (Lie and other) | 27, 39 | | Jensen F. — Introduction to Computational Chemistry | 257 | | Ryder L.H. — Quantum Field Theory | 216 | | Gracia-Bondia J.M., Varilly J.C., Figueroa H. — Elements of Noncommutative Geometry | 564 | | Hogben L. — Handbook of Linear Algebra | 59—10 | | Fradkin E. — Field theories of condensed matter systems | 195 | | Greiner W. — Quantum mechanics. An introduction | 446 | | Billinge S.J.L., Thorpe M.F. — Local structure from diffraction | 212 | | Shankar R. — Basic Training In Mathematics | 271 | | Itoh K., Fukayama A. — Transport and Structural Formation in Plasmas | 122 | | Mensky M.B. — Continuous quantum measurements and path integrals | 5, 36, 50 | | Isihara A. — Statistical physics | 277, 286ff, 310ff | | Rammer J. — Quantum transport theory | 6, 22, 23, 88 | | Ziman J.M. — Elements of Advanced Quantum Theory | see also “Green function” | | Griffits D.J. — Introduction to quantum mechanics | 372 | | Dittrich T. (ed.), Hanggi P. (ed.), Ingold G.-L. (ed,) — Quantum transport and dissipation | 16, 230, 256, 268 | | Hughes I.S. — Elementary Particles | 245 | | Thaller B. — The Dirac equation | 117 | | Muta T. — Foundations of Quantum Chromodynamics | 62, 85 | | Prigogine I. — Nonequilibrium statistical mechanics | 118, 119, 120, 122, 123, 124, 276, 295, 296 | | Gottfried K., Weisskopf V.F. — Concepts of particle physics (volume 2) | 230 | | Green M.B., Schwarz J.H., Witten E. — Superstring Theory (vol. 1) | 28, 355 | | Rickayzen G. — Green's functions and condensed matter | 56—57, 59, see also “Green's functions” | | Atkinson D., Johnson P.W. — Exercises in Quantum Field Theory: A Self-Contained Book of Questions and Answers | 151 | | Visser M. — Lorentzian wormholes. From Einstein to Hawking | 282, 334 | | Collins P.D., Squires E.J., Martin A.D. — Particle Physics and Cosmology | 40 | | Elze H.-T. (ed.) — Decoherence and entropy in complex systems | 45, 47, 137, 154 | | Griffits D. — Introduction to elementary particles | 203, 357 | | Deligne P., Kazhdan D., Etingof P. — Quantum fields and strings: A course for mathematicians (Vol. 1) | 29, 426, 529, 1188 | | Borne T., Lochak G., Stumpf H. — Nonperturbative quantum field theory and the structure of matter | 88f, 91 | | Bogolubov N.N., Logunov A.A., Todorov I.T. — Introduction to Axiomatic Quantum Field Theory | 459—460, 575 (see also “Green functions, causal”) | | Reed M., Simon B. — Methods of Modern mathematical physics (vol. 2) Fourier analysis, self-adjointness | 60, 282 | | Fetter A.L., Walecka J.D. — Quantum theory of many-particle systems | see Green’s functions at zero temperature; Polarization propagator | | Nakamura K., Harayama T. — Quantum chaos and quantum dots | 61 | | Collins P.D.B., Martin A.D., Squires E.J. — Particle Physics and Cosmology | 40 | | Schulman L.S. — Techniques and applications of path integration | 7 | | ter Haar D. — Elements of Statistical Mechanics | 301 | | Greiner W., Reinhardt J. — Quantum electrodynamics | 46 | | Exner P. — Open quantum systems and Feynman integrals | 5, 98, 159, 259 | | Araki H. (ed.), Ezawa H. (ed.) — Topics in the Theory of Schrödinger Operators | 11 | | Zee A. — Quantum field theory in a nutshell | 22—23 | | Economou E.N. — Green's Functions in Quantum Physics | 23, 133, 144, 280 | | Ambjorn J., Durhuus B., Jonsson T. — Quantum Geometry: A Statistical Field Theory Approach | 18 | | Halzen F., Martin A.D. — Quarks and Leptons: An Introductory Course in Modern Particle Physics | 82, 135 | | Siegel W. — Fields | VA-B | | Wald R.M. — Quantum field theory in curved spacetime and black hole thermodynamics | see "Feynmann propagator", "Green's functions", "Two-point function" | | Grosche C., Steiner F. — Handbook of Feynman path integrals | see Path integral | | Christensen S.M. — Quantum theory of gravity | 212, 257, 258, 268 | | Accardi L., Lu Y.G., Volovich I. — Quantum Theory and Its Stochastic Limit | 9 | | Gottfried K., Weisskopf V.F. — Concepts of Particle Physics | 40 | | Friedlander F.G. — The Wave Equation on a Curved Space-Time | see "Transport bitensor" | | Tsang L., Kong J.A., Ding K.- H. — Scattering of electromagnetic waves (Vol 2. Numerical simulations) | 377 | | Goldenfeld N. — Lectures on Phase Transitions and the Renormalization Group | 367 | | Prigogine I. — Monographs in Statistical Physics And Thermodynamics. Volume 1. Non-equilibrium statistical mechanics | 118, 119, 120, 122, 123, 124, 276, 295, 296 | | Gallavotti G. — Statistical Mechanics | 253 | | Kreimer D. — Knots and Feynman Diagrams | 11, 14, 16 | | Mandel L., Wolf E. — Optical Coherence and Quantum Optics | 188, 390 | | Rauch J. — Partial differential equations | 134, Ch. 4 | | Povh B., Rith K., Scholz C., Zetsche F. — Particles and nuclei. An introduction to the Physical Concepts | 52, 60, 134 | | Siegel W. — Fields | VA-B | | Carroll R.W. — Mathematical physics | 290 | | Avramidi I.G. — Heat Kernel and Quantum Gravity | 2, 11, 96, 97 | | Greiner W., Reinhardt J. — Field quantization | see "Feynman propagator" | | Richards P.I. — Manual of Mathematical Physics | 138 | | Mohapatra R.N. — Massive Neutrinos in Physics and Astrophysics | 286, 288, 291, 294 | | Prigogine I. (ed.), Rice S.A. (ed.) — Advances in Chemical Physics. Volume XXXVI | 50 | | Gould H., Tobochnik J., Christian W. — An introduction to computer simulation methods | 707 | | Ambjorn J., Durhuus B., Jonsson T. — Quantum Geometry. A Statistical Field Theory Approach | 18 | | Thaller B. — The Dirac equation | 117 | | Hooft G.T. — Under the spell of the gauge principle | 34, 37, 38 | | Benfatto G., Gallavotti G. — Renormalization Group | 7, 13, 19, 24, 30, 56, 59, 68, 75, 81, 85, 92, 104, 109, 124, 126 | | Cvitanovic P., Artuso R., Dahlqvist P. — Classical and quantum chaos | 482 | | Deligne P., Kazhdan D., Etingof P. — Quantum fields and strings: A course for mathematicians | 29, 426, 529, 1188 | | Deligne P., Etingof P., Freed D. — Quantum fields and strings: A course for mathematicians, Vol. 2 (pages 727-1501) | 29, 426, 529, 1188 | | Flügge S. (ed.) — Encyclopedia of Physics (Volume 3/2 Principles of Thermodynamics and Statistics) | 341—343 | | Zeidler E. — Applied Functional Analysis: Applications to Mathematical Physics | 387 | | Tsang L., Kong J.A. — Scattering of electromagnetic waves (Vol 3. Advanced topics) | 181 | | Vafa C., Zaslow E. — Mirror symmetry | 668 | | Schiff L.I. — Quantum Mechanics | 300 | | Ticciati R. — Quantum field theory for mathematicians | 106 | | Salmhofer M. — Renormalization: an introduction | 22 | | Zeidler E. — Oxford User's Guide to Mathematics | 438, 454 | | Brown L., Dresden M., Hoddeson L. — Pions to quarks: Particle physics in the 1950s | 616 | | Schwinger J. — Particles, Sources, And Fields. Volume 3 | see "Propagation function" | | Constantinescu F., Magyari E. — Problems in quantum mechanics | 131 | | Simeone C. — Deparametrization and Path Integral Quantization of Cosmological Models | 15, 29, 31, 33, 34, 50, 51, 55, 57, 67, 71, 72, 88, 102, 106, 108, 117, 119, 121 | | Kardar M. — Statistical physics of fields | 76, 77 | | Breuer H.-P., Petruccione F. — The Theory of Open Quantum Systems | 15 | | ter Haar D. — Elements of Statistical Mechanics | 301 | | Kleinert H. — Gauge fields in condensed matter (part 2) | 36, 174 | | Kane G.L. — Modern elementary particle physics | 30, 33 | | Bettini A. — Introduction to Elementary Particle Physics | 174, 176, 181 | | Collins P.D.B., Martin A.D., Squires E.J. — Particle Physics and Cosmology | 40 | | Rivasseau V. — From Perturbative to Constructive Renormalization | 24, 28, 34, 61—62, 156, 293, 303 | | Fetter A.L., Walecka J.D. — Quantum theory of many-particle systems | see "Green's functions at zero temperature", "Polarization propagator" | | Bellac M. — Thermal Field Theory (Cambridge Monographs on Mathematical Physics) | 27, 38, 48, 49 | | Plischke M., Bergersen B. — Equilibrium statistical physics | 468 | | Exner P. — Open quantum systems and Feynman integrals | 5, 98, 159, 259 |
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