| Êíèãà | Ñòðàíèöû äëÿ ïîèñêà |
| Chung T.J. — Computational fluid dynamics | 352, 904—11 |
| Zinn-Justin J. — Quantum field theory and critical phenomena | 809 |
| Bird R.B., Lightfoot E.N., Stewart W.E. — Transport Phenomena | see “Interfacial tension” |
| Zinn-Justin J. — Quantum field theory and critical phenomena | 722 |
| Finlayson B.A. — Numerical Methods for Problems With Moving Fronts | 429 |
| Allen M.P., Tildesley D.J. — Computer simulation of liquids | 289 |
| Frenkel D., Smit B. — Understanding Molecular Simulation: from algorithms to applications | 472 |
| Wiese J., Shems E. — Weird Science: 40 Strange-Acting, Bizarre-Looking, and Barely Believable Activities for Kids | 11—12 |
| Gooding K.M., Regnier F.E. — HPLC of biological macromolecules | 146—151 |
| Kundu P.K., Cohen I.R. — Fluid mechanics | 8 |
| Clift R., Grace J.R., Weber M.E. — Bubbles, drops, and particles | see Interfacial tension |
| Nayfeh A.H., Mook D.T. — Nonlinear Oscillations | 615 |
| Drazin P. — Introduction to Hydrodynamic Stability | 57, 59, 62 |
| Parisi G. — Statistical field theory | 208, n. 41 |
| Aris R. — Vectors, Tensors and the Basic Equations of Fluid Mechanics | 231, 234 |
| Bloomer J.J. — Practical fluid mechanics for engineering applications | 198 |
| Batchelor G.K. — An Introduction to Fluid Dynamics | 60 |
| Debnath L. — Nonlinear water waves | 7, 76, 92, 100, 102, 159, 469 |
| Huang K. — Statistical Mechanics | 36 |
| Dill K.A., Bromberg S. — Molecular Driving Forces: Statistical Thermodynamics in Chemistry and Biology | 154, 262 |
| Chaudhry M.A., Zubair S.M. — On a Class of Incomplete Gamma Functions with Applications | 329 |
| Safran S.A. — Statistical thermodynamics on surfaces, interfaces and membranes | 58, 60, 68, 74, 76, 82, 90, 201 |
| Gleick J. — Chaos. Making a new science | 311 |
| Chaikin P.M., Lubensky T.C. — Principles of condensed matter physics | 481, 486, 635—638 |
| Domb C., Green M.S. (eds.) — Phase Transitions and Critical Phenomena (Vol. 1) | 229 |
| Isihara A. — Statistical physics | 164 |
| Gompper G., Schick M. — Self-Assembling Amphiphilic Systems | see “Interfacial tension” |
| Toda M., Kubo R., Saito N. — Statistical Physics I: Equilibrium Statistical Mechanics, Vol. 1 | 106, 109 |
| Lerner K.L., Lerner B.W. — The gale encyclopedia of science (Vol. 6) | 6:3915—3916, 6:3916 |
| Huey E.G. — What makes the wheels go round? A first-time physics | 99—105 |
| Langmuir I. — Phenomena, Atoms and Molecules | 39, 42, 44, 68, 73, 81, 94, 97, 227, 233, 236, 241, 259, 271, 272, 282 |
| Schroeder M.R. — Schroeder, Self Similarity: Chaos, Fractals, Power Laws | 200 |
| Ablowitz M.J., Segur H. — Solitons and the Inverse Scattering Transform | 260, 268, 277, 280, 289—292, 319, 322 |
| Rubinstein M., Colby R.H. — Polymer Physics | 175, 194 |
| Pippard A.B. — The Elements of Classical Thermodynamics | 84 |
| Hiemenz P.C. (ed.), Rajagopalan R. (ed.) — Principles of colloid and surface chemistry | 248, 251, 276—283, 289, 301, 327, 329, 487—489 |
| Adkins C.J. — Equilibrium Thermodynamics | 128—132, 208—212, 243 |
| Pedregal P. — Introduction to Optimization | 150 |
| Brillouin L. — Wave Propagation in Periodic Structures | 30 |
| Forsythe W.E. — Smithsonian Physical Tables | 361 |
| Seitz F. — Modern Theory of Solids | 98 |
| Guggenheim E.A. — Thermodynamics | 46, see also “Interfacial tension” |
| Unertl W.N. — Physical Structure | 55, 56, 57, 58, 63, 65, 69, 81, 114, 301 |
| Billingham J., King A.C. — Wave Motion | 74, 76, 94, 125, 307 |
| Feynman R.P., Leighton R.B., Sands M. — The Feynman lectures on physics (vol.2) | II-12-5 |
| McHardy J., Sawan S.P. — See Inside! Supercritical Fluid Cleaning by Samuel P. Haber: Book Cover * o Table of Contents Supercritical Fluid Cleaning: Fundamentals, Technology and Applications | 34, 122, 198, 277 |
| Povey M.J. — Ultrasonic Techniques for Fluids Characterization | 138 |
| Visser M. — Lorentzian wormholes. From Einstein to Hawking | 160, 164 |
| Sinai Ya.G. — Theory of Phase Transitions: Rigorous Results | 57 ff. |
| Walker J. — The flying circus of physics: with answers | 3.5, 3.102, 3.108, 3.109, 4.13, 4.101, 4.114—4.117, 4.119—4.121 |
| Balian R. — From Microphysics to Macrophysics: Methods and Applications of Statistical Physics (vol. 1) | 245, 299—301 |
| Douglas Clark C.Y. — The Electronic Structure and Properties of Matter: An Introductory Study of Certain Properties of Matter in the Light of Atomic Numbers, Being Volume I of a Comprehensive Treatise | 15, 33Ca, b, 34 |
| Sernelius B.E. — Surface Modes in Physics | 233 |
| Binks B.P., Horozov T. — Colloidal Particles at Liquid Interfaces | 462, 463 |
| Kompaneyets A.S., Yankovsky G. — Theoretical Physics | 583 |
| Tullis J.P. — Hydraulics of Pipelines: Pumps, Valves, Cavitation Transients | 6 |
| Durand-Vidal S., Simonin J.-P., Turq P. — Electrolytes at interfaces | 207, 208, 211, 214, 215, 217, 218, 221—223, 225, 228 |
| Israelachvili J.N. — Intermolecular and surface forces | 8, 131, 201—204, 258, 312—313 (see also “Surface energy”) |
| Ambjorn J., Durhuus B., Jonsson T. — Quantum Geometry: A Statistical Field Theory Approach | 97 |
| Pozrikidis C. — Fluid Dynamics: Theory, Computation, and Numerical Simulation | 174 |
| Gurtin M.E. — Thermomechanics of evolving phase boundaries in the plane | 32 |
| Mattheij R.M.M. — Partial differential equations: modeling, analysis, computation | 120, 498 |
| Stewart I.W. — The Static and Dynamic Continuum Theory of Liquid Crystals: A Mathematical Introduction | 120, 122, 123, 329 |
| Oprea J. — Differential Geometry and Its Applications | 161 |
| Cotterill R.M.J. — Biophysics: An Introduction | 162 |
| Prigogine I. — Proceedings of the International Symposium on Transport. Processes in Statistical Mechanics, held in Brussels,. August 27-31, 1956 | 257—271 |
| Eringen A.C. (ed.) — Continuum physics (vol. 4) Polar and Nonlocal Field Theories | 95 ff., 207, 264 |
| Thompson Philip A. — Compressible-fluid dynamics | 17 |
| Leverenz H.W. — An introduction to luminescence of solids | 34 |
| Kimball A.I. — A college textbook of physics | 163 |
| Azaroff L.V. — Introduction to Solids | 113 |
| Batchelor G. — Introduction to Fluid Dynamics | 60 |
| Huggins E.R. — Physics 2000 | 17—14 |
| Weinberg S. — The Quantum Theory of Fields. Vol. 3 Supersymmetry | 330—1 |
| Gallavotti G. — Statistical Mechanics | 205, 221 |
| Ilachinski A. — Cellular automata. A discrete universe | 129 |
| Alder B., Fernbach S., Rotenberg M. — Methods in computational physics. Volume 3. Fundamental methods in hydrodynamics | 170 |
| Weinberg S. — The Quantum Theory of Fields. Vol. 2 Modern Applications | 426, 468 |
| Yang W. — Fluidization, Solids Handling, and Processing: Industrial Applications | 382 |
| Steen W.M. — Laser material Processing | 114, 122, 196 |
| Itzykson C., Drouffe J-M. — Statistical field theory. Vol. 1 | 85 |
| Sverdrup H.U., Johnson M.W., Fleming R.H. — The Oceans: their physics, chemistry, and general biology | 70 |
| Fluegge S. (ed.) — Encyclopedia of physics. Vol. 9. Fluid dynamics III | 352, 451, 452, 460, 614, 631, 638 |
| Alder B. (ed.), Fernbach S. (ed.), Rotenberg M. (ed.) — Methods in computational physics: advances in research and applications. Volume 3. Fundamental methods in hydrodynamics | 170 |
| Reif F. — Fundamentals of statistical and thermal physics | 196—197 |
| Anderson J.B. — Quantum Monte Carlo: Origins, Development, Applications | 27 |
| Almgren F.J. — Plateau's Problem: An Invitation to Varifold Geometry | 9 |
| Chaikin P., Lubensky T. — Principles of condensed matter physics | 481, 486, 635—8 |
| Kambhampati D. (ed.) — Protein Microarray Technology | 180 |
| Richards P.I. — Manual of Mathematical Physics | 28, 43 |
| Brewer D.F. — Progress in Low Temperature Physics. Volume X | 231, 358 |
| Banyai L., Koch S.W. — Semiconductor quantum dots | 216 |
| Ambjorn J., Durhuus B., Jonsson T. — Quantum Geometry. A Statistical Field Theory Approach | 97 |
| Acheson D.J. — Elementary Fluid Dynamics | 57, 74, 112, 305, 313 |
| Hugh D. Young, Roger A. Freedman — University physics with modern physics | 465, 745 |
| Ferrario M., Ciccotti G., Binder K. — Computer Simulations in Condensed Matter Systems. Volume 2 | 202 |
| Hobbie R., Roth B. — Intermediate Physics for Medicine and Biology, | 65, 77 |
| Friedlander S.(ed.), Serre D.(ed.) — Handbook of Mathematical Fluid Dynamics | 446 |
| Guyon E., Hulin J., Petit L. — Physical Hydrodynamics | 31—40 |
| Seitz F. — Solid State Physics. Volume 3 | 237 |
| Borówko M. (ed.) — Computational Methods in Surface and Colloid Science | 280, 558, 597, 641, 642, 856, 868, 877, 895, 913, see also "Interfacial tensions" |
| Kruegel E. — The Physics of Interstellar Dust | 296, 317 |
| Kubo R. — Thermodynamics | 192, 213, 229 |
| Langhaar H.R. — Energy Methods in Applied Mechanics | 31 |
| Langhaar H.R. — Energy Methods in Applied Mechanics | 31 |
| Pitts D.R., Sissom L.E. — Schaum's outline of theory and problems of heat transfer | 247 |
| Worsnop B.L., Flint H.T. — Advanced Practical Physics for Students | 124 |
| Kardar M. — Statistical physics of fields | 16, 49, 197, 283 |
| Lienhardt J.H. IV, Lienhardt J.H. V — A heat transfer textbook | 465—467 |
| Fung Y. — A First Course in Continuum Mechanics: for Physical and Biological Engineers and Scientists | 235—237 |
| Mattheij R.M. — Partial differential equations | 120, 498 |
| Feynman R., Leighton R., Sands M. — Lectures on Physics 2 | II-12-5 |
| Meyer-Ortmanns H., Reisz T. — Principles of phase structures in particle physics | 184, 197, 582 |
| Springford M. — Electrons at Fermi surface | 134 |
| Blin-Stoyle R.J. — Eureka! Physics of particles, matter and the universe | 45, 134 |
| Braides A. — Gamma-convergence for Beginners | 5 |
| Reichl L.E. — Modern Course in Statistical Physics | 20, 142—146 |
| Buchdahl H.A. — The Concepts of Classical Thermodynamics | 149, 195, 201 |
| Lipparini E. — Modern many-particle physics: atomic gases, quantum dots and quantum fluids | 115, 377, 380, 420 |
| Plischke M., Bergersen B. — Equilibrium statistical physics | 163—165, 168, 169 |
| Andrea Braides — Gamma-convergence for Beginners (Oxford Lecture Series in Mathematics and Its Applications, 22) | 5 |
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