| Êíèãà | Ñòðàíèöû äëÿ ïîèñêà |
| Wolf E.L. — Nanophysics and nanotechnology. An introduction to modern concepts in nanoscience | |
| Heinbockel J.H. — Introduction to tensor calculus and continuum mechanics | 212 |
| Zienkiewicz O.C., Taylor L.R. — The finite element method (vol. 2, Solid mechanics) | 272, 369 |
| Showalter R.E. — Monotone Operators in Banach Space and Nonlinear Partial Differential Equations | 257 |
| Weinstock R. — Calculus of variations with applications to physics & engineering | 203 |
| Nayfeh A.H. — Perturbation Methods | 36 |
| Benson D. — Mathematics and music | 114, 122 |
| Goldstein H., Poole C., Safko J. — Classical mechanics | 559, 560 |
| Nayfeh A.H., Mook D.T. — Nonlinear Oscillations | 448, 487, 502, 524, 544, 545, 571 |
| Murnaghan F.D. — Finite deformation of an elastic solid | 103, 111 |
| Sadd M.H. — Elasticity: theory, applications, and numerics | 74, 77 |
| Becker A.A. — The Boundary Element Method in Engineering. A complete course | 64, 81, 99 |
| Winterbone D.E. — Advanced thermodynamics for engineers | 123 |
| Browne M.E. — Schaum's outline of theory and problems of physics for engineering and science | 154, 208 |
| Atkinson K.E., Han W. — Theoretical Numerical Analysis: A Functional Analysis Framework | 345 |
| Planck M. — Introduction to Theoretical Physics | 182 |
| Antman S.S. — Nonlinear Problems of Elasticity | 592 |
| Guimaraes A.P. — Magnetism and Magnetic Resonance in Solids | 128 |
| Rubinstein M., Colby R.H. — Polymer Physics | 296, 304 |
| Zauderer E. — Partial Differential Equations of Applied Mathematics | 166, 328, 332 |
| Ewald P.P. — The physics of solids and fluids | 21, 54, 58, 59 |
| Iesan D. — Saint-Venant's Problem | 8 |
| Fishbane P.M. — Physics For Scientists and Engineers with Modern Physics | 326—321, 408 |
| Cleland A.N. — Foundations of nanomechanics | 187, 191, 192 |
| Structure Property Relationships in Polimers | 39, 67 |
| Karman T., Biot A.M. — Mathematical Methods in Engineering | 209 |
| Zeldovich Ya.B., Yaglom I.M. — Higher Math for Beginners | 115 |
| Libai A., Simmonds J.G. — The Nonlinear Theory of Elastic Shells | 25, 37, 82, 83, 111, 145, 180, 182, 188, 191, 415, 476, 485, 504, 506 |
| Unertl W.N. — Physical Structure | 94, 635 |
| Barber J.R. — Elasticity | 18 |
| Peiser H.S, (ed.), Rooksby H.P. (ed.), Wilson A.J.C. (ed.) — X-Ray Diffraction by Polycrystalline Materials. Physics in Industry | 416, 474—475, 608 |
| Eschenauer H., Olhoff N., Schnell W. — Applied structural mechanics : fundamentals of elasticity, load-bearing structures, structural optimization | 32, 37, 94 |
| Sedov L. — Similarity and Dimensional Methods in Mechanics | 114 |
| Freund L.B. — Dynamic Fracture Mechanics | 24 |
| Roskam J. — Airplane flight dynamics and automatic flight controls (part 1) | 7 27 |
| Strelkov S.P. — Mechanics | 289 |
| Ding H., Chen W., Zhang L. — Elasticity of Transversely Isotropic Materials | 21, 157, 274 |
| Sokolnikoff I.S. — Tensor Analysis: Theory and Applications to Geometry and Mechanics of Continua | 317 |
| Mattheij R.M.M. — Partial differential equations: modeling, analysis, computation | 121 |
| Adachi S. — Physical Properties of III-V Semiconductor Compounds InP, InAs, GaAs, GaP, InGaAs, and InGaAsP | 24, 265 |
| van der Giesen E. (Editor), Wu T.Y. (Editor) — Solid Mechanics, Volume 36 | 138 |
| Holmes R.A. — Physical Principles of Solid State Devices | 242 |
| Arya A.P. — Introduction to Classical Mechanics | 369 |
| Eringen A.C., Suhubi E.S. — Elastodynamics (vol.1) Finite motions | 63 |
| Dekker A.J. — Solid State Physics | 79 |
| Sokolnikoff I.S. — Mathematical Theory of Elasticity | 68, 111 |
| Azaroff L.V. — Introduction to Solids | 126 |
| Brandt D.A., Warner J.C. — Metallurgy Fundamentals | 55 |
| Riley, Hobson — Mathematical Methods for Physics and Engineering | 610, 802 |
| Accetta J.S. (ed.), Shumaker D.L. (ed.), Rogatto W.D. (ed.) — The Infrared & Electro-Optical Systems Handbook. Volume 3: Electro-Optical Components | 10—11 |
| Patnaik S., Hopkins D. — Strength of Materials: A New Unified Theory for the 21st Century | 29, 33 |
| Stratton J.A. — Electromagnetic Theory | 95 |
| McEvily A.J. — Metal Failures: Mechanisms, Analysis, Prevention | 24, 42 |
| Churchill R.V. — Operational mathematics | 92, 110 |
| Gedde U.W. — Polymer Physics (Chapman 1995) | 213 |
| Hugh D. Young, Roger A. Freedman — University physics with modern physics | 364, 365 |
| Marder M.P. — Condensed matter physics | 293, 301 |
| Tenenbaum M., Pollard H. — Ordinary differential equations: an elementary textbook for students of mathematics, engineering, and the sciences | 385 |
| Hobbie R., Roth B. — Intermediate Physics for Medicine and Biology, | 12, 344 |
| Callen H.B. — Thermodynamics | 230 |
| Ashby N., Miller S.C. — Principles of modern physics | 348 |
| Synge J.L., Griffith B.A. — Principles of Mechanics | 96, 114 |
| Hearn E.J. — Mechanics of Materials (vol. 1) An Introduction to the Mechanics of Elastic and Plastic Deformation of Solids and Structural Materials | 3, 361 |
| Langhaar H.R. — Energy Methods in Applied Mechanics | 125 |
| Langhaar H.R. — Energy Methods in Applied Mechanics | 125 |
| Lee A. — Mathematics Applied to Continuum Mechanics | 161 |
| Worsnop B.L., Flint H.T. — Advanced Practical Physics for Students | 83 |
| Popov E.P. — Engineering Mechanics of Solids | 66 |
| Silva V.D. — Mechanics and Strength of Materials | 124 |
| Villaggio P. — Mathematical models for elastic structures | 31 |
| Slater J., Frank N. — Introduction to Theoretical Physics | 182 |
| Seitz F. (ed.), Turnbull D. (ed.) — Solid State Physics. Advances in Research and Applications. Volume 16 | 280 |
| Mattheij R.M. — Partial differential equations | 121 |
| Demidovich B.P., Maron I.A. — Computational Mathematics | 44 |
| Feynman R., Leighton R., Sands M. — Lectures on Physics 2 | II-38-2 |
| Askeland D.R. — The Science and Engineering of Materials | see "Modulus of elasticity" |
| Springford M. — Electrons at Fermi surface | 290 |
| Benoit H. (ed.), Cantow H.-J. (ed.), Dall'Asta G. (ed.) — Polymer Physics | 154 |
| Synge J. L. — Tensor Calculus | 212 |
| Melissinos A.C. — Principles of modern technology | 325 |
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