| Êíèãà | Ñòðàíèöû äëÿ ïîèñêà |
| Wolf E.L. — Nanophysics and nanotechnology. An introduction to modern concepts in nanoscience | |
| Misner C.W., Thorne K.S., Wheeler J.A. — Gravitation | see “Heat conduction” |
| Finlayson B.A. — Numerical Methods for Problems With Moving Fronts | 416 |
| Allen M.P., Tildesley D.J. — Computer simulation of liquids | 61 |
| Wilcox D. — Turbulence modeling for CFD | 175 |
| Wesseling P. — Principles of computational fluid dynamics | 20 |
| Frenkel D., Smit B. — Understanding Molecular Simulation: from algorithms to applications | 90 |
| Zienkiewicz O.C., Taylor L.R. — The finite element method (vol. 3, Fluid dynamics) | 8, 65, 66, 156, 159, 161 |
| Versteeg H.K., Malalasekera W. — An introduction to computational fluid dynamics | 88 |
| Weinberger H.F. — First course in partial defferential equations with complex variables and transform methods | 58 |
| Kundu P.K., Cohen I.R. — Fluid mechanics | 6 |
| Liboff R. — Kinetic Theory | 175, 185, 202 |
| Sadd M.H. — Elasticity: theory, applications, and numerics | 320 |
| Wesson J. — Tokamaks | 88, 93 |
| Batchelor G.K. — An Introduction to Fluid Dynamics | 34 |
| Huang K. — Statistical Mechanics | 107 |
| Dill K.A., Bromberg S. — Molecular Driving Forces: Statistical Thermodynamics in Chemistry and Biology | 323 |
| Chaudhry M.A., Zubair S.M. — On a Class of Incomplete Gamma Functions with Applications | 331, 336, 347, 410, 441, 442 |
| Debnath L. — Nonlinear Partial Differential Equations for Scientists and Engineers | 52 |
| Poprawe R. (ed.), Loosen P., Bachmann F. — High Power Diode Lasers: Technology and Applications | 107, 287, 396 |
| Franklin P. — Fourier Methods | 101 |
| Mobley R.K. — Plant Engineering Handbook | 140—141 |
| Williams B.W. — Power Electronics | 7, 99, 103 |
| Winterbone D.E. — Advanced thermodynamics for engineers | 298 |
| Debnath L. — Linear Partial Differential Equations for Scientists and Engineers | 75, 481 |
| Powers D.L. — Boundary Value Problems: And Partial Differential Equations | 137 |
| Ablowitz M.J., Fokas A.S. — Complex Variables: Introduction and Applications | 325 |
| Elliott R.J., Gibson A.F. — An Introduction to Solid State Physics and Its Applications | see Heat transport |
| Raabe D. — Computational materials science | 50 |
| Balescu R. — Equilibrium and nonequilibrium statistical mechanics | 428, 461, 465, 467, 674 |
| Jones R.M. — Mechanics of composite materials | 2 |
| Chaikin P.M., Lubensky T.C. — Principles of condensed matter physics | 425 |
| Isihara A. — Statistical physics | 15, 16, 99, 271, 340, 343, 345, 346, 352, 354 |
| Rammer J. — Quantum transport theory | 217 |
| Newman J.R. — The World of Mathematics, Volume 1 | 219 |
| Planck M. — Introduction to Theoretical Physics | 197 |
| Cantwell B.J., Crighton D.G. (Ed), Ablowitz M.J. (Ed) — Introduction to Symmetry Analysis | 19, 20, 293 |
| Dienes G.J., Vineyard G.H. — Radiation Effects in Solids | 96—98 |
| Menzel D.H. — Mathematical Physics | 11 |
| Ready J.F., Farson D.F. — LIA handbook of laser materials processing | 74, 75, 170, 172, 173, 186, 193, 200, 201, 309, 310, 313, 326, 329, 348, 355, 363, 365, 375, 376, 378, 379, 380, 387, 392, 445, 446, 447, 472, 600 |
| Fundamentals of engineering. Supplied-reference handbook | 59 |
| Ablowitz M.J., Segur H. — Solitons and the Inverse Scattering Transform | 3 |
| Sokolnikoff I.S. — Mathematics of Physics and Modern Engineering | 415, 455 |
| Fishbane P.M. — Physics For Scientists and Engineers with Modern Physics | 524, 538, 541 |
| Staff of Research and Education Association — The Thermodynamics Problem Solver: A Complete Solution Guide to Any Textbook | 13-3, 13-6, 13-8, 13-10, 13-17, 13-25, 13-35 |
| Cleland A.N. — Foundations of nanomechanics | 133 |
| Prigogine I. — Nonequilibrium statistical mechanics | 61 |
| Structure Property Relationships in Polimers | 35, 36, 88, 89, 92 |
| Stakgold I. — Green's Functions and Boundary Value Problems | 3 |
| Reist P.C. — Aerosol Science and Technology | 40—42, 168, 171 |
| Sakai K. (ed.) — Terahertz Optoelectronics | 168 |
| Koerber G.G. — Properties of Solids | 13, 18—20, 69, 129, 142, 187, 195—201,225—228 |
| Bube R.H. — Electronic Properties of Crystalline Solids: An Introduction to Fundamentals | 211 |
| Forsythe W.E. — Smithsonian Physical Tables | 9 |
| Newman J.R. (ed.) — The World of Mathematics, Volume 4 | 219 |
| Libai A., Simmonds J.G. — The Nonlinear Theory of Elastic Shells | 48, 145, 327 |
| Rickayzen G. — Green's functions and condensed matter | 119, 200 |
| Barber J.R. — Elasticity | 203 |
| Feynman R.P., Leighton R.B., Sands M. — The Feynman lectures on physics (vol.2) | II-2-8, II-12-2 |
| Hayes W.D., Probstein R.F. — Hypersonic Flow Theory | 287 |
| Johnson K., Lark-Horovitz V.A. — Methods of Experimental Physics Solid State Physics (Volume 6/PartA) | 385—405 |
| Kubo R. — Statistical Mechanics: An Advanced Course with Problems and Solutions | see “Heat conductivity” |
| MacRobert T.M. — Spherical Harmonics an Elementary Treatise on Harmonic Functions with Applications | 23 |
| Raizer Yu.P. — Gas Discharge Physics | 277 |
| Kittel Charles, Kroemer Herbert — Thermal Physics | 401, 421 |
| Anderson P.W. — The theory of superconductivity in the high-Tc curprates | 76—80, 129, 201 |
| Jeffrey A., Taniuti T. — Mathematics in Science and Engineering: volume 9. Non-linear wave propagation | 58, 169 |
| Dresselhaus M.S., Dresselhaus G., Avouris Ph. — Carbon nanotubes | 291 |
| Wolf E.L. — Nanophysics and nanotechnology: an introduction to modern concepts in nanoscience | 5, 22, 114 |
| Hanna J.R., Rowland J.H. — Fourier Series, Transforms, and Boundary Value Problems | 236 |
| Mason G.W., Griffen D.T., Merrill J. — Physical Science Concepts | 184-185, 188-189, 374 |
| Asmar N.H. — Partial Differential Equations with fourier series and boundary value problems | 143 |
| Animalu A.O. — Intermediate Quantum Theory of Crystalline Solids | 138 |
| Ahrens T.J. — Rock Physics and Phase Relations. A Handbook of Physical Constants | 105—126 |
| ter Haar D. — Elements of Statistical Mechanics | 55, 143 |
| Olver P.J., Shakiban C. — Applied linear. algebra | 592 |
| Economou E.N. — Green's Functions in Quantum Physics | 25 |
| Pfeiler W. — Alloy Physics: A Comprehensive Reference | 132, 149, 151 If |
| de Groot S.R., Mazur P. — Non-equilibrium thermodynamics | 41—42, 71, 235—238, 280—281, 294—300, 360 |
| Bernard P.S., Wallace J.M. — Turbulent Flow: Analysis, Measurement and Prediction | 25, 49, 57 |
| Padmanabhan T. — Theoretical Astrophysics: Volume 1, Astrophysical Processes | 369 |
| Prigogine I. — From being to becoming: time and complexity in the physical sciences. | 162 |
| Bird R.B., Armstrong R.C., Hassager O. — Dynamics of polymeric liquids (Vol. 1. Fluid mechanics) | (1)11, 206, 208 |
| Prigogine I. — Proceedings of the International Symposium on Transport. Processes in Statistical Mechanics, held in Brussels,. August 27-31, 1956 | 385, 369, 378, 382, 420 |
| Gao W., Sammes N. — An Introduction to Electronic and Ionic Materials | 206, 223 |
| Curle N., Davies H. — Modern Fluid Dynamics. Volume 1. Incompressible flow | 142, 143 |
| Margenau H., Murphy G.M. — The mathematics of physics and chemistry | 35 |
| Thompson Philip A. — Compressible-fluid dynamics | see "Conductivity" |
| Sone Y. — Molecular Gas Dynamics Theory, Techniques, and Applications | 6 |
| Ashcroft N.W., Mermin N.D. — Solid State Physics | see "Conductivity thermal" |
| Eliezer Sh., Ghatak A., Hora H. — Fundamentals of Equations of State | 15 |
| Àìåíçàäå Þ.À. — Òåîðèÿ óïðóãîñòè | 86 |
| Stavroulakis I.P., Tersian S.A. — Partial Differential Equations: An Introduction with Mathematica and Maple | 97 |
| Toro E.F. — Riemann Solvers and Numerical Methods for Fluid Dynamics: A Practical Introduction | 17 |
| Prigogine I. — Monographs in Statistical Physics And Thermodynamics. Volume 1. Non-equilibrium statistical mechanics | 61 |
| Brandt D.A., Warner J.C. — Metallurgy Fundamentals | 62 |
| Domb C.M., Green M. — Phase Transitions and Critical Phenomena: Series Expansion for Lattice Models, Vol. 3 | 649 |
| Fox W.P., Goirdano F.R., Weir M.D. — First Course in Mathematical Modeling | 325 |
| Accetta J.S. (ed.), Shumaker D.L. (ed.), Rogatto W.D. (ed.) — The Infrared & Electro-Optical Systems Handbook. Volume 3: Electro-Optical Components | 7—8, 46, 52—56, 346—354, 370—372 |
| Yang W. — Fluidization, Solids Handling, and Processing: Industrial Applications | 130, 186 |
| Shockley W. — Imperfections in Nearly Perfect Crystals: Symposium held at Pocono Manor | 18, 64 |
| Weaver H.J. — Applications of discrete and continous Fourier analysis | 295 |
| Gallavotti G. — Foundations of fluid mechanics | 430 |
| Tykodi R.J. — Thermodynamics of steady states | 131ff. |
| Lindsay R.B. — Mechanical Radiation | 266, 306 |
| Sverdrup H.U., Johnson M.W., Fleming R.H. — The Oceans: their physics, chemistry, and general biology | see also "Eddy conductivity", 60, 61 |
| Reif F. — Fundamentals of statistical and thermal physics | 478—479 |
| Bridgman P.W. — Dimensional Analysis | 92 |
| Chaikin P., Lubensky T. — Principles of condensed matter physics | 425 |
| Stakgold I. — Green's functions and boundary value problems | 3 |
| Richards P.I. — Manual of Mathematical Physics | 56, 57, 188 |
| Saito Y. — Statistical physics of crystal growth | 67, 102, 149 |
| Gould H., Tobochnik J., Christian W. — An introduction to computer simulation methods | 296, 664 |
| Hugh D. Young, Roger A. Freedman — University physics with modern physics | 592, 851 |
| Marder M.P. — Condensed matter physics | 327, 455, 475 |
| Tenenbaum M., Pollard H. — Ordinary differential equations: an elementary textbook for students of mathematics, engineering, and the sciences | 185 |
| Hobbie R., Roth B. — Intermediate Physics for Medicine and Biology, | 103, 382 |
| David A. Mooney — Introduction to Thermodynamics and Heat Transfer | 342 |
| Hildebrand F.B. — Advanced Calculus for Applications | 428 |
| Guyon E., Hulin J., Petit L. — Physical Hydrodynamics | 9—18 |
| Wrede R.C., Spiegel M. — Theory and problems of advanced calculus | 356, 357 |
| Boyd R.W. — Nonlinear Optics | 221, 392 |
| Kubo R. — Thermodynamics | 37 |
| Easterling K.E. — Introduction to the physical metallurgy of welding | 22—23 |
| Spitzer L.Jr. — Physics of Fully Ionized Gases Interscience Tracts on Physics and Astronomy No. 3 | 86—88 |
| Wilson A.H. — The Theory of Metals | 200ff, 307ff |
| Haile J.M. — Molecular Dyanmics Simualtion: Elementary Methods | 301, 306 |
| Haile J.M. — Molecular Dyanmics Simualtion: Elementary Methods | 301, 306 |
| Librescu L., Song O. — Thin-Walled Composite Beams:Theory and Application | 313, 417 |
| Librescu L., Song O. — Thin-Walled Composite Beams:Theory and Application | 313, 417 |
| Pitts D.R., Sissom L.E. — Schaum's outline of theory and problems of heat transfer | 1, 2, 3, 7, 8, 12 |
| Rice F.O., Teller E. — The structure of matter | 167 |
| Lienhardt J.H. IV, Lienhardt J.H. V — A heat transfer textbook | 10—16, 51 |
| ter Haar D. — Elements of Statistical Mechanics | 55, 143 |
| Slater J., Frank N. — Introduction to Theoretical Physics | 197 |
| Groesen E., Molenaar J. — Continuum Modeling in the Physical Sciences (Monographs on Mathematical Modeling and Computation) | 23, 44, 54 |
| Shu-Ang Zhou — Electrodynamics of solids and microwave superconductivity | 151, 581 |
| Feynman R., Leighton R., Sands M. — Lectures on Physics 2 | II-2-8, II-12-2 |
| Ehrenberg W. — Electric Conduction in Semiconductors and Metals | 1, 20, 61, 67, 74, 198 |
| Askeland D.R. — The Science and Engineering of Materials | 736, 742 |
| Springford M. — Electrons at Fermi surface | 76, 109, 112 |
| Blin-Stoyle R.J. — Eureka! Physics of particles, matter and the universe | 43 |
| Bird R.B., Curtiss C.F., Armstrong R.C. — Dynamics of Polymeric Liquids. Vol. 2. Kinetic Theory | (1)11, 206, 208 |
| Kittel C. — Introduction to solid state physics | 131, 166 |
| Plischke M., Bergersen B. — Equilibrium statistical physics | 503—507, 510 |
| Cushman-Roisin B. — Introduction to geophysical fluid dynamics | 35 |
| Sedov L.I. — Introduction to the mechanics of a continous medium | 165 |
| Helander P., Sigmar D.J. — Collisional Transport in Magnetized Plasmas | see "heat conductivity" |
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