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Ïîèñê êíèã, ñîäåðæàùèõ: Order parameter
| Êíèãà | Ñòðàíèöû äëÿ ïîèñêà | | Kogut J.B., Stephanov M.A. — The Phases of Quantum Chromodynamics: From Confinement to Extreme Environments | | | Anderson P.W. — Basic notions of condensed matter physics | | | Cardy J. — Scaling and renormalization in statistical physics | | | Sornette D. — Critical phenomena in natural sciences | | | Schmalzried H. — Chemical Kinetics of Solids | 298 | | Gomez C., Ruiz-Altaba M., Sierra G. — Quantum Groups in Two-Dimensional Physics | 273 | | Zinn-Justin J. — Quantum field theory and critical phenomena | 529 | | Di Francesco P., Mathieu P., Senechal D. — Conformal field theory | 73 | | Zinn-Justin J. — Quantum field theory and critical phenomena | 502 | | Herrmann H.J. (ed.), Roux S. (ed.) — Statistical models for the fracture of disordered media | 122, 217 | | McCammon A.J., Harvey S. — Dynamics Of Proteins And Nucleic Acids | 100—102 | | Stauffer D., Aharony A. — Introduction To Percolation Theory | 138 | | Dill K.A., Bromberg S. — Molecular Driving Forces: Statistical Thermodynamics in Chemistry and Biology | 481, 494 | | Safran S.A. — Statistical thermodynamics on surfaces, interfaces and membranes | 61, 175 | | Efetov K. — Supersymmetry in disorder and chaos | 59, 65, 319 | | Heermann D.W. — Computer Simulation Methods in Theoretical Physics | 75, 85 | | Tarantello G. — Self-Dual Gauge Field Vortices: An Analytical Approach | 4 | | Fradkin E. — Field theories of condensed matter systems | 48, 85, 103, 317, 323 | | Itoh K., Fukayama A. — Transport and Structural Formation in Plasmas | 146, 160, 248 | | Balescu R. — Equilibrium and nonequilibrium statistical mechanics | 180, 297, 314 | | Thouless D.J. — Topological quantum numbers in nonrelativistic physics | 4—14, 23, 24, 26—28, 35—37, 39—44, 46, 52, 55—67, 78, 89, 92—97, 99, 100, 102—104, 108, 114, 347 | | Getzlaff M. — Fundamentals of Magnetism | 71, 79 | | Chorin A.J. — Vorticity and turbulence | 114, 115 | | Yeomans J.M. — Statistical Mechanics of Phase Transitions | 1 | | Domb C., Green M.S. (eds.) — Phase Transitions and Critical Phenomena (Vol. 1) | 84 | | Haken H. — Laser light dynamics (volume 2) | 169, 176, 314 | | Kadanoff L.P. — Statistical physics | 239, 383 | | Wagner M. — Unitery Transformations in Solid State Physics | 143, 145, 146 | | Dorlas T.C. — Statistical mechanics, fundamentals and model solutions | 168 | | Stauffer D., Aharony A. — Introduction to percolation theory | 138 | | Janot C. — Quasicrystals | 347 | | Schroeder M.R. — Schroeder, Self Similarity: Chaos, Fractals, Power Laws | 347 | | Guimaraes A.P. — Magnetism and Magnetic Resonance in Solids | 74—75, 78—79 | | Rubinstein M., Colby R.H. — Polymer Physics | 173, 214 | | van Baal P. (ed.) — Confinement, duality, and non-perturbative aspects of QCD | 216, 243, 252, 343, 347, 416, 424, 529, 530, 536 | | Nagaosa N. — Quantum field theory in condensed matter physics | 55, 67 | | Hilborn R.C. — Chaos and nonlinear dynamics | 328 | | Stanley H.E. — Introduction to phase transitions, and critical phenomena | 3, 9ff, 20, 33 | | Rickayzen G. — Green's functions and condensed matter | 259, 270, 310, 319 | | Kubo R. — Statistical Mechanics: An Advanced Course with Problems and Solutions | 307 | | Stone M. — The physics of quantum fields | 120 | | Kittel Charles, Kroemer Herbert — Thermal Physics | 298 | | Cowan B. — Topics In Statistical Mechanics | 149, 150, 153, 181 | | Kenzel W., Reents G., Clajus M. — Physics by Computer | 199 | | Huang K. — Introduction to Statistical Physics | 189, 190, 195 | | Gruener G. — Density waves in solids | 11, 37, 39, 46, 49, 65, 66, 67, 75, 78, 85, 87, 88, 101, 106, 108 | | Tsytovich V.N. (Ed), Morfill G.E. (Ed) — Elementary Physics of Complex Plasmas | 252 | | Orlando T.P., Delin K.F. — Foundations of Applied Superconductivity | 495 | | Landau L.D., Lifshitz E.M. — Statistical physics (volume 5 of Course of Theoretical Physics) | 449 | | Fetter A.L., Walecka J.D. — Quantum theory of many-particle systems | 431 | | Schulman L.S. — Techniques and applications of path integration | 254 | | Nicolis G., Prigogine I. — Self-organization in nonequilibrium systems | 116, 322, 326 | | Baxter R.J. — Exactly Solved Models in Statistical Mechanics | see also spontaneous magnetization and spontaneous polarization | | Pfeiler W. — Alloy Physics: A Comprehensive Reference | 360, 547, 552 | | Volovik G. — Artificial black holes | 184, 187 | | Pathria P.K. — Statistical Mechanics | 341—342, 346, 364, 386—387, 446 | | Mourachkine A. — High-Temperature Superconductivity in Cuprates: The Nonlinear Mechanism and Tunneling Measurements | 6, 20, 22, 68, 87, 92, 190—191, 194—195, 205, 209, 231, 233—237, 240, 248—249, 252—253, 272, 283, 290, 292, 294 | | Thomas A.W., Weise W. — The structure of the nucleon | 149 | | Akhmediev N., Ankiewicz A. — Dissipative Solitons | 269, 345 | | Tinkham M. — Introduction to superconductivity | 55, 112 (see also Energy gap) | | Goldenfeld N. — Lectures on Phase Transitions and the Renormalization Group | 9, 18, 65, 136 | | Ilachinski A. — Cellular automata. A discrete universe | 339 | | Callen H. — Thermodynamics and an Introduction to Thermostatistics | 255, 256, 263 | | Domb C.M., Green M. — Phase Transitions and Critical Phenomena: Series Expansion for Lattice Models, Vol. 3 | 502, 571, 572, 579, 580, 583, 596, 611, 630, 631, 646, 647, 648, 649 | | Aitchison I.J.R. — An Informal Introduction to Gauge Field Theories | 77 | | Mandel L., Wolf E. — Optical Coherence and Quantum Optics | 914 | | Northolt M.G. — Separation Techniques Thermodynamics Liquid Crystal | 132—137 | | Haken H. — Synergetics: an introduction | 14, 15, 180, 195, 198, 199, 227, 303, 307 | | Roepstorf G. — Path integral approach to quantum physics | 267 | | Christe P., Henkel M. — Introduction to conformal invariance and its applications to critical phenomena | 3, 42, 110 | | Greiner W., Neise L., Stöcker H. — Thermodynamics and statistical mechanics | 417 | | Brewer D.F. — Progress in Low Temperature Physics. Volume X | 3, 4, 5, 10, 13, 16, 17, 28, 33, 61 | | Gould H., Tobochnik J., Christian W. — An introduction to computer simulation methods | 472, 620 | | Rubinstein I. — Electro-diffusion of ions | 52, 53 | | Ferrario M., Ciccotti G., Binder K. — Computer Simulations in Condensed Matter Systems. Volume 2 | 195 | | Henkel M. — Conformal Invariance and Critical Phenomena | 5, 68, 160, 349 | | Greiner W., Neise L., Stocker H. — Thermodynamics and statistical mechanics | 417 | | Hartmann A.K., Rieger H. — Optimization Algorithms in Physics | 78, 84, 138 | | Chandler D. — Introduction to modern statistical mechanics | 127 | | Haile J.M. — Molecular Dyanmics Simualtion: Elementary Methods | 117—120, 131, 143—144, 205, 209, 211, 221, 222, 436, 455 | | Haile J.M. — Molecular Dyanmics Simualtion: Elementary Methods | 117—120, 131, 143—144, 205, 209, 211, 221, 222, 436, 455 | | Smith R. — Smart material systems: model development | 282 | | Binder K., Heermann D.W. — Monte Carlo Simulation in Statistical Physics | 35, 42, 48, 49 | | Kardar M. — Statistical physics of fields | 11, 20, 29, 176 | | Glimm J., Jaffe A. — Quantum Physics: A Functional Integral Point of View | 80 | | Morandi G. — Statistical Mechanics: An Intermediate Course | 204, 209 ff, 382 ff | | Shu-Ang Zhou — Electrodynamics of solids and microwave superconductivity | 321 | | Davies P. — The New Physics | 216, 336, 341 | | Kleinert H. — Gauge fields in condensed matter (part 2) | 261, 269, 329 | | Meyer-Ortmanns H., Reisz T. — Principles of phase structures in particle physics | 18, 172, 244, 449, 450, 586 | | Reichl L.E. — Modern Course in Statistical Physics | 97 | | Fetter A.L., Walecka J.D. — Quantum theory of many-particle systems | 431 | | Lipparini E. — Modern many-particle physics: atomic gases, quantum dots and quantum fluids | 255, 256, 259, 376, 388 | | Kittel C. — Introduction to solid state physics | 658 | | Plischke M., Bergersen B. — Equilibrium statistical physics | 63—65, 67, 68, 71, 73, 74, 80, 83—86, 90, 92, 94, 95, 97, 99, 100, 104, 105, 111—113, 116, 118—123, 126, 137, 138, 184, 194, 210, 217, 364, 368 | | Iwamoto M., Chen-Xu W. — The Physical Properties of Organic Monolayers | 51 |
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