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| Ðåçóëüòàò ïîèñêà |
Ïîèñê êíèã, ñîäåðæàùèõ: Specific heat
| Êíèãà | Ñòðàíèöû äëÿ ïîèñêà | | Cardy J. — Scaling and renormalization in statistical physics | | | Gomez C., Ruiz-Altaba M., Sierra G. — Quantum Groups in Two-Dimensional Physics | 301 | | Di Francesco P., Mathieu P., Senechal D. — Conformal field theory | 62 | | Zinn-Justin J. — Quantum field theory and critical phenomena | 567 | | Wesseling P. — An introduction to multigrid methods | 212 | | Allen M.P., Tildesley D.J. — Computer simulation of liquids | see “Heat capacity” | | Gilkey P.B., Leahy J.V., Park J. — Spinors, Spectral Geometry, and Riemannian Submersions | 86 | | Enns R.H., Mc Guire G.C. — Nonlinear physics with mathematica for scientists and engineers | 252 | | Zienkiewicz O.C., Taylor L.R. — The finite element method (vol. 3, Fluid dynamics) | 64, 92, 121, 156, 170 | | Weinberger H.F. — First course in partial defferential equations with complex variables and transform methods | 58 | | Showalter R.E. — Monotone Operators in Banach Space and Nonlinear Partial Differential Equations | 241, 243, 244 | | Aris R. — Vectors, Tensors and the Basic Equations of Fluid Mechanics | 251 | | Jaswon M.A. — The Theory of Cohesion. An Outline of the Cohesive Properties of Electrons in Atoms, Molecules and Crystals | 127, 128 | | Huang K. — Statistical Mechanics | 4 | | Becker A.A. — The Boundary Element Method in Engineering. A complete course | 239 | | Chaudhry M.A., Zubair S.M. — On a Class of Incomplete Gamma Functions with Applications | 442 | | Bitsadze A.V. — Equations of mathematical physics | 43 | | Bergman S., Schiffer M. — Kernel Functions and Elliptic Differential Equations in Mathematical Physics | 2 | | Von Laue M. — History of Physics | 95, 98, 134 | | Honerkamp J. — Statistical Physics | 76 | | Serre D. — Handbook of Mathematical Fluid Dynamics, Vol. 1 | 20, 43 | | Browne M.E. — Schaum's outline of theory and problems of physics for engineering and science | 209 | | Strauss W.A. — Partial Differential Equations: An Introduction | 16 | | Elliott R.J., Gibson A.F. — An Introduction to Solid State Physics and Its Applications | 76 | | Mayer J.E., Mayer M.G. — Statistical Mechanics | see “Heat capacity” | | Neittaanmaki P., Tiba D. — Optimal Control of Nonlinear Parabolic Systems: Theory, Algorithms and Applications | 5 | | Alexiades V. — Mathematical Modeling of Melting and Freezing Processes | 8, 9 | | Planck M. — Treatise on thermodynamics | 35 | | Sloane N.J.A. — Handbook of Integer Sequences | 1271, 1520, 1777, 1963, 2055, 2066, 2187 | | Finch S.R. — Mathematical constants | 399 | | Fermi E. — Thermodynamics | 21 | | Friedlander S.J. (Ed), Serre D. (Ed) — Handbook of Mathematical Fluid Dynamics, Vol. 3 | 62 | | Bamberg P.G. — A Course in Mathematics for Students of Physics, Vol. 2 | 787 | | Thouless D.J. — Topological quantum numbers in nonrelativistic physics | 88, 102 | | Getzlaff M. — Fundamentals of Magnetism | 79 | | Yeomans J.M. — Statistical Mechanics of Phase Transitions | 1, 3, 17, 18, 25 | | Walecka J.D. — Fundamentals of statistical mechanics | 106, 109, 208, 277, 280, 282 | | Chaikin P.M., Lubensky T.C. — Principles of condensed matter physics | 115, 231, 425 | | Born M. — Natural philosophy of cause and chance (The Waynflete lectures) | 44, 80, 116—119, 150, 159, 173 | | Domb C., Green M.S. (eds.) — Phase Transitions and Critical Phenomena (Vol. 1) | 180, 190, 249, 266, 273, 301, 302, 310, 314, 315, 317, 318 | | Feynman R.P., Leighton R.B., Sands M. — The Feynman lectures on physics (vol.1) | 40—7 f, 45—2 | | Isihara A. — Statistical physics | 15, 54, 76, 91, 94, 97, 180, 229, 243, 249, 255, 258, 259, 306, 392 | | Mihaly L., Martin M.C. — Solid state physics. Problems and solutions | 38, 55, 62, 198 | | Rammer J. — Quantum transport theory | 147, 217 | | Zel'dovich Ya.B., Raizer Yu.P. — Physics of Shock Waves and High-Temperature Hydrodynamic Phenomena (vol. 1) | 177, 179 | | Toda M., Kubo R., Saito N. — Statistical Physics I: Equilibrium Statistical Mechanics, Vol. 1 | 67 | | Dorlas T.C. — Statistical mechanics, fundamentals and model solutions | 17, 30 | | Giamarchi T. — Quantum Physics in One Dimension | 40 | | Szekeres P. — A Course in Modern Mathematical Physics: Groups, Hilbert Space and Differential Geometry | 464 | | Lin C.C., Segel L.A. — Mathematics Applied to Deterministic Problems in the Natural Sciences | 481 | | Janot C. — Quasicrystals | 378, 383, 397 | | Galindo A., Pascual P. — Quantum Mechanics Two | II 242 | | Menzel D.H. — Mathematical Physics | 11 | | Ready J.F., Farson D.F. — LIA handbook of laser materials processing | 472 | | Perry J. — The Calculus for Engineers | 139 | | Langmuir I. — Phenomena, Atoms and Molecules | 139, 204 | | Schroeder M.R. — Schroeder, Self Similarity: Chaos, Fractals, Power Laws | 40, 353 | | Guimaraes A.P. — Magnetism and Magnetic Resonance in Solids | 75, 90 | | Ewald P.P. — The physics of solids and fluids | 100, 111, 112 | | Sokolnikoff I.S. — Mathematics of Physics and Modern Engineering | 415 | | Schercliff J.A. — Vector Fields | 139, 278 | | Fishbane P.M. — Physics For Scientists and Engineers with Modern Physics | 518 | | Staff of Research and Education Association — The Thermodynamics Problem Solver: A Complete Solution Guide to Any Textbook | 4-5, 4-8, 4-10, 4-14, 4-22, 4-23, 4-35, 4-39, 7-3, 7-4, 7-9, 7-10 | | Cleland A.N. — Foundations of nanomechanics | 33 | | Structure Property Relationships in Polimers | 23, 33, 122 | | Born M. — Atomic Physics | 8, 194—200 | | Stakgold I. — Green's Functions and Boundary Value Problems | 3 | | Koerber G.G. — Properties of Solids | 118, 187, 190—194 | | Brillouin L. — Wave Propagation in Periodic Structures | 45, 158, 167 | | Angrist S.W., Hepler L.G. — Laws of Order and Chaos | 67, 188 | | Forsythe W.E. — Smithsonian Physical Tables | 9, 155 | | Kubo R., Toda M., Hashitsume N. — Statistical physics II. Nonequilibrium statistical mechanics | 184 | | Rickayzen G. — Green's functions and condensed matter | 45, 314, 321, 326 | | Unertl W.N. — Physical Structure | 535, 633, 749 | | Cracknell A.P., Wong K.C. — The Fermi Surface: Its Concept, Determination and Use in the Physics of Metals | 147, 162—165, 169, 264, 320, 368, 386, 397, 404, 405, 410, 416, 424—428, 431, 452—453, 469, 496, 499, see also “Magnetothermal oscillations” | | Barber J.R. — Elasticity | 203 | | Billingham J., King A.C. — Wave Motion | 241, 259 | | Feynman R.P., Leighton R.B., Sands M. — The Feynman lectures on physics (vol.2) | I-40-7 f, I-45-2, II-37-4 | | Povey M.J. — Ultrasonic Techniques for Fluids Characterization | 34, 44, 76, 101, 109, 128 | | Johnson K., Lark-Horovitz V.A. — Methods of Experimental Physics Solid State Physics (Volume 6/PartA) | see “Heat capacity” | | Stuwe K. — Geodynamics of the Lithosphere: An Introduction | 54, 56 | | MacRobert T.M. — Spherical Harmonics an Elementary Treatise on Harmonic Functions with Applications | 24 | | Lieberman M.A., Lichtenberg A.J. — Principles of Plasma Discharges and Materials Processing | 36 | | Oden J.T. — Finite Elements: An Introduction (Vol. 1) | 129, 247 | | Zel'dovich Ya.B., Raizer Yu.P. — Physics of Shock Waves and High-Temperature Hydrodynamic Phenomena (vol. 2) | 177, 179 | | Kittel Charles, Kroemer Herbert — Thermal Physics | 63 | | Stoner E.C. — Magnetism and Atomic Structure with 56 diagrams | 93 | | Anderson P.W. — The theory of superconductivity in the high-Tc curprates | 229 | | Bryan G.H. — Thermodynamics: an introductory treatise | 7, 21, 118 | | Dresselhaus M.S., Dresselhaus G., Avouris Ph. — Carbon nanotubes | 280, 283 | | Kenzel W., Reents G., Clajus M. — Physics by Computer | 199 | | Gautreau R., Savin W. — Schaum's Outline of Modern Physics | 296 | | Huang K. — Introduction to Statistical Physics | 6 | | Gruener G. — Density waves in solids | 47, 49, 55, 58, 104, 123, 124, 161, 162 | | Hanna J.R., Rowland J.H. — Fourier Series, Transforms, and Boundary Value Problems | 236 | | Bitsadze A.V. — Equations of Mathematical Physics | 43 | | Deák P. — Computer Simulation of Materials at Atomic Level | 468 | | Asmar N.H. — Partial Differential Equations with fourier series and boundary value problems | 143 | | Orlando T.P., Delin K.F. — Foundations of Applied Superconductivity | see Heat capacity | | Landau L.D., Lifshitz E.M. — Statistical physics (volume 5 of Course of Theoretical Physics) | 46, 451—6 | | Efros A.L. (ed.), Pollak M. (ed.) — Electron-electron interactions in disordered systems | 262-265, 441 | | Fetter A.L., Walecka J.D. — Quantum theory of many-particle systems | see Heat capacity | | Kleinert H., Schulte-Frohlinde — Critical Properties of (Phi)P4-Theories | 173 | | Bracewell R.N. — The Fourier Transform and its applications | 476 | | Carrol B.W., Ostlie D.A. — An introduction to modern astrophysics | 318—320 | | Mehta M.L. — Random Matrices | 64, 65, 228 | | ter Haar D. — Elements of Statistical Mechanics | 117, 123, 130 | | Hoddeson L., Daitch V. — True Genius: The Life and Science of John Bardeen | 59 | | Slater J.C. — Introduction To Chemical Physics | 17—20, 22—23 | | Baxter R.J. — Exactly Solved Models in Statistical Mechanics | 16 | | Fersht A. — Structure and Mechanism in Protein Science | 510, 511, 513, 545—547 | | Economou E.N. — Green's Functions in Quantum Physics | 25, 334 | | Slater J.C. — Quantum Theory of Atomic Structure vol1 | 15 | | Ambjorn J., Durhuus B., Jonsson T. — Quantum Geometry: A Statistical Field Theory Approach | 134, 262 | | Carslaw H.S. — Conduction of Heat in Solids | 9 | | Ding H., Chen W., Zhang L. — Elasticity of Transversely Isotropic Materials | 190 | | Poincare H. — Mathematics and Science: Last Essays | 77, 79, 80, 94, 95 | | Mattheij R.M.M. — Partial differential equations: modeling, analysis, computation | 119 | | Wilson A.J.C. — X-ray optics;: The diffraction of X-rays by finite and imperfect crystals | see “Heat capacity”, 141 | | Bernard P.S., Wallace J.M. — Turbulent Flow: Analysis, Measurement and Prediction | 24, 55 | | Prigogine I. — From being to becoming: time and complexity in the physical sciences. | 91 | | Cotterill R.M.J. — Biophysics: An Introduction | 80 | | Mihalas D., Mihalas B.W. — Foundations of Radiation Hydrodynamics | 186—187 | | Gao W., Sammes N. — An Introduction to Electronic and Ionic Materials | 203, 223 | | Pathria P.K. — Statistical Mechanics | 15, 54, 61, 454, 455, 456 | | Amit D.J. — Field theory, the renormalization group, and critical phenomena | 5, 20, 28—29, 31, 108, 143, 210—212, 294, 321, 343 | | Anisimov S.I., Khokhlov V.A. — Instabilities in Laser-matter interaction | 10, 126, 131 | | Eringen A.C., Suhubi E.S. — Elastodynamics (vol.1) Finite motions | 56 | | Eliezer Sh., Ghatak A., Hora H. — Fundamentals of Equations of State | 18, 37 | | Àìåíçàäå Þ.À. — Òåîðèÿ óïðóãîñòè | 86 | | Leverenz H.W. — An introduction to luminescence of solids | 143 | | Schmittmann B., Zia R.K.P. — Phase Transitions and Critical Phenomena (vol. 17) | 47, 58 | | Kimball A.I. — A college textbook of physics | 261 | | Rice J. — Introduction to statistical mechanics for students of physics and physical chemistry | 65, 123, 164, 166, 277 | | Dekker A.J. — Solid State Physics | 32 ff. | | Baez J.C., Muniain J.P. — Gauge theories, knots, and gravity | 333 | | Farges J. (ed.) — Organic conductors: fundamentals and applications | 182, 387, 446 | | Curle N., Davies H. — Modern Fluid Dynamics. Compressible flow | 16 | | Kleinert H. — Gauge fields in condensed matter (part 4) | 890 | | Tinkham M. — Introduction to superconductivity | 64—66 | | Bracewell R. — The Fourier Transform and Its Applications | 476 | | Bird G.A. — Molecular gas dynamics and the direct simulation of gas flows | 25 | | Goldenfeld N. — Lectures on Phase Transitions and the Renormalization Group | 18 | | Rosenberg H.M. — Low temperature solid state physics. Some selected topics | 1 ff | | Gallavotti G. — Statistical Mechanics | 71, 91, 92, 93, 99 | | Brandt D.A., Warner J.C. — Metallurgy Fundamentals | 63 | | Domb C.M., Green M. — Phase Transitions and Critical Phenomena: Series Expansion for Lattice Models, Vol. 3 | 58, 87, 201, 219, 249, 252, 256, 281, 290, 294, 311, 313, 324, 362, 413, 436, 438, 439, 442, 454, 459, 466, 496, 507, 534, 535, 540, 551, 552, 554, 584, 594, 595, 637, 643, 645, 649 | | Knight J. — Science of everyday things (volume 4). Real-life earth science | 1:17—18, 2:219, 2:230 | | Accetta J.S. (ed.), Shumaker D.L. (ed.), Rogatto W.D. (ed.) — The Infrared & Electro-Optical Systems Handbook. Volume 3: Electro-Optical Components | 7, 49, 354—357 | | Mayer J.E., Goeppert Mayer M. — Statistical mechanics | see "Heat capacity" | | Mendelsohn K. — Cryophysics | 34—36, 55—57, 72, 80, 84, 102—105, 130, 153 | | Sverdrup H.U., Johnson M.W., Fleming R.H. — The Oceans: their physics, chemistry, and general biology | 61, 62 | | Lamb H. — Statics. Including Hydrostatics and the Elements of the Theory of Elasticity | 2o5 | | Christe P., Henkel M. — Introduction to conformal invariance and its applications to critical phenomena | 3, 42, 109 | | Reif F. — Fundamentals of statistical and thermal physics | 139 | | Chaikin P., Lubensky T. — Principles of condensed matter physics | 115, 231, 425 | | Goldsmid H.J. (ed.) — Problems in solid state physics | see "Heat capacity" | | Stakgold I. — Green's functions and boundary value problems | 3 | | Zallen R. — The Physics of Amorphous Solids | 17—19 | | Choquard P.F. — The anharmonic crystal | 17, 121, 252 | | Ambjorn J., Durhuus B., Jonsson T. — Quantum Geometry. A Statistical Field Theory Approach | 134, 262 | | Acheson D.J. — Elementary Fluid Dynamics | 79, 307 | | Ferrario M., Ciccotti G., Binder K. — Computer Simulations in Condensed Matter Systems. Volume 2 | 9, 13 | | Planck M. — Scientific Autobiography And Other Papers | 49 | | David A. Mooney — Introduction to Thermodynamics and Heat Transfer | 32—35, 38, 52, 54 | | Schwarzenbach D. — Crystallography | 197, 198 | | Hildebrand F.B. — Advanced Calculus for Applications | 428 | | HarrisR. — Nonclassical physics: beyond Newton's view | 176, 388—397 | | Hoyer U. — Work on Atomic Physics (1912 - 1917) | 126, 162, 224, (261), (289), (312), 338, 342, 416, 421—422, (434), 452, 455f., 458—459, 563, 567, 589, 604 | | Henkel M. — Conformal Invariance and Critical Phenomena | 5, 68, 78, 160 | | Wrede R.C., Spiegel M. — Theory and problems of advanced calculus | 356, 357 | | Koonin S.E., Meredith D.C. — Computational Physics-Fortran Version | 217 | | Boyd R.W. — Nonlinear Optics | 392 | | Kruegel E. — The Physics of Interstellar Dust | 168ff | | Sommerfeld A. — Thermodynamics and Statistical Mechanics | 6, 16, 17, 227f., 234f. | | Abrikosov A.A., Gorkov L.P., Dzyalosliinski I.E. — Methods of quantum fields theory in statistical physics | 166ff., 188, 302ff. | | Hartmann A.K., Rieger H. — Optimization Algorithms in Physics | 75, 85, 187, 288 | | Kubo R. — Thermodynamics | 11, 19, 137 | | Zeidler E. — Oxford User's Guide to Mathematics | 372, 493 | | Easterling K.E. — Introduction to the physical metallurgy of welding | 19, 20, 24 | | Smith R. — Smart material systems: model development | 268 | | Binder K., Heermann D.W. — Monte Carlo Simulation in Statistical Physics | 55, 63, 119, 123, 130, 139, 143 | | Pitts D.R., Sissom L.E. — Schaum's outline of theory and problems of heat transfer | 4 | | Bohm-Vitense E. — Introduction to Stellar Astrophysics: Volume 3 | 54 | | Ericksen J.L. — Introduction to the Thermodynamics of Solids | 31—33, 120, 154—155 | | Courant R. — Differential and Integral Calculus, Vol. 1 | 123 | | Lyons L. — All You Wanted to Know about Mathematics but Were Afraid to Ask - Mathematics for Science Students. Volume 1 | 208 | | ter Haar D. — Elements of Statistical Mechanics | 117, 123, 130 | | Abrikosov A.A., Gîr'kov L.P., Dzyalosiiinskh I.Yk. — Quantum field theoretical methods in statistical physics | 166ff., 188, 302ff. | | Mattheij R.M. — Partial differential equations | 119 | | Cercignani C. — Rarefied Gas Dynamics | 27, 54, 56, 204, 305 | | Feynman R., Leighton R., Sands M. — Lectures on Physics 2 | I-40-7 f, I-45-2, II-37-4 | | Davies P. — The New Physics | 211—212, 214, 217—218, 220—222, 226 | | Kleinert H. — Gauge fields in condensed matter (part 2) | 8, 260, 299, 303, 417, 509 | | Mackey G. — Unitary Group Representations in Physics, Probability and Number Theory | 274 | | Askeland D.R. — The Science and Engineering of Materials | 220, 242, 729, 742 | | Meyer-Ortmanns H., Reisz T. — Principles of phase structures in particle physics | 18 | | Springford M. — Electrons at Fermi surface | 73 | | Fetter A.L., Walecka J.D. — Quantum theory of many-particle systems | see "Heat capacity" | | Buchdahl H.A. — The Concepts of Classical Thermodynamics | 85, 105, 107, 111, 118, 147, 164, 179, 181, 183, 185, 191, 215 | | Badii R., Politi A. — Complexity: Hierarchical structures and scaling in physics | 128 | | Buckmaster J. — The Mathematics of combustion | 3, 5, 6, 136 | | Lipparini E. — Modern many-particle physics: atomic gases, quantum dots and quantum fluids | 23, 28—30, 61, 252 | | Lin C., Segel L. — Mathematics Applied to Deterministic Problems in the Natural Sciences | 481 | | Lin C., Segel L. — Mathematics Applied to Deterministic Problems in the Natural Sciences | 481 | | Plischke M., Bergersen B. — Equilibrium statistical physics | 1, 14, 19, 25, 27, 28, 59, 75, 84, 200, 209, 211, 220, 356, 357, 365 | | Bok J., Deutscher G., Pavuna D. — The gap symmetry and fluctuations in High-Tc conductors | 20, 47, 81, 160, 403, 456, 478 | | Lin C., Segel L. — Mathematics applied to deterministic problems in the natural sciences | 481 | | Kalckar J. — Foundations of Quantum Physics I (1926 - 1932), Volume 6 | 145, 158, 396 | | Honerkamp J. — Statistical physics: an advanced approach with applications | 76 | | Ferziger J.H., Kaper H.G. — Mathematical theory of transport processes in gases | 198, 215, 338, 393 | | Poynting J.H., Sir Thomson J.J. — Heat (A text book of physics): Eighth Edition | 65, 66, 288—290 |
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