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Ïîèñê êíèã, ñîäåðæàùèõ: Scattering amplitude
| Êíèãà | Ñòðàíèöû äëÿ ïîèñêà | | Taylor M.E. — Partial Differential Equations. Qualitative studies of linear equations (vol. 2) | 152, 161, 190, 208, 211, 348 | | Ito K. — Encyclopedic Dictionary of Mathematics. Vol. 2 | 375.C 386.B | | Mahan G.D. — Many-particle physics | 918 | | Morse P., Feshbach H. — Methods of Theoretical Physics (part 1) | 1065, 1069, 1070, 1167 | | Morse P., Feshbach H. — Methods of Theoretical Physics (part 2) | 1065, 1069, 1070, 1167 | | Ammari H., Hyeonbae Kang — Reconstruction of Small Inhomogeneities from Boundary Measurements | 209 | | Atkins P.W., Friedman R.S. — Molecular Quantum Mechanics | 476 | | Ryder L.H. — Quantum Field Theory | 165 | | Serre D. — Handbook of Mathematical Fluid Dynamics, Vol. 1 | 47 | | Reed M., Simon B. — Methods of Modern mathematical physics (vol. 3) Scattering theory | 111, 127 | | Bohren C.F., Huffman D.R. — Absorption and Scattering of Light by Small Particles | 70, 71 (see also “Amplitude scattering matrix”) | | Egorov Y.U. (Ed), Gamkrelidze R.V. (Ed) — Partial Differential Equations I: Foundations of the Classical Theory | 193 | | Ziman J.M. — Elements of Advanced Quantum Theory | 127, 207, 209, 212 | | Domb C., Lebowitz J.L. — Phase Transitions and Critical Phenomena (Vol. 19) | 86, 87, 101, 111, 115, 166 | | Ito K. — Encyclopedic Dictionary of Mathematics | 375.C, 386.B | | Galindo A., Pascual P. — Quantum Mechanics Two | II 27 | | Brown L.S. — Quantum Field Theory | 150 | | Waseda Y. — Novel Application of Anomalous (Resonance) X-Ray Scattering for Structural Characterization of Disordered Materials | 101 | | Greiner W., Schramm S., Stein E. — Quantum chromodynamics | 33, 39, 52, 57 | | Bailin D., Love A. — Introduction to Gauge Field Theory | 51—59, 67, 69 | | Englert B.G. (Ed) — Quantum Mechanics | 370 | | Meyerhof W.E. — Elements of Nuclear Physics | 235 | | Griffits D. — Introduction to elementary particles | 119 (see also “Amplitude”) | | Bethe H.A., Salpeter E.E. — Quantum Mechanics of One-and-Two-Electron Atoms | 33 | | Martin B.R., Shaw G. — Particle Physics | 17, 294—297 | | Perkins D.H. — Particle Astrophysics | 25 | | Fetter A.L., Walecka J.D. — Quantum theory of many-particle systems | 128—130, 143—146, 314 | | Bernstein R.B. — Atom-Molecule Collision Theory: Guide for the Experimentalist | 145, 146, 160, 162, 164, 167, 169—172, 177, 185, 186, 273—275, 308—314, 316, 318-321, 323, 333, 334, 336, 346, 446 | | Collins P.D.B., Martin A.D., Squires E.J. — Particle Physics and Cosmology | 20 | | Egorov Y.V., Shubin M.A. — Partial Differential Equations I (Foundations of the Classical) | 193 | | Araki H. (ed.), Ezawa H. (ed.) — Topics in the Theory of Schrödinger Operators | 98 | | Greiner W. — Classical electrodynamics | 402 | | Bates D.R. — Quantum Theory | 311 | | Shankar R. — Principles of quantum mechanics | 527 | | Murrel J.N., Bosanac S.D. — Introduction to the Theory of Atomic and Molecular Collisions | 33, 38, 44, 89, 97, 149 | | Tsang L., Kong J.A., Ding K.- H. — Scattering of electromagnetic waves (Vol 1. Theories and applications) | 2, 6, 68 | | Tsang L., Kong J.A., Ding K.- H. — Scattering of electromagnetic waves (Vol 2. Numerical simulations) | 659 | | Goertzel G. — Some Mathematical Methods of Physics | 184 | | Nouredine Z. — Quantum Mechanics: Concepts and Applications | 599—606 | | Akhiezer A.I., Berestetskii V.B. — Quantum electrodynamics | 40 | | Amrein W.O., Sinha K.B., Jauch J.M. — Scattering Theory in Quantum Mechanics: Physical Principles and Mathematical Methods | 286—293, 339, 421—426, 448, 465—468, 514—516, 518—519, 525—526, 627—628 | | Nishijima K. — Fundamental particles | 96 | | Morse P.M. — Methods of theoretical physics | 1065, 1069, 1070, 1167 | | Rodin Y.L. — Generalized Analytic Functions On Riemann Surfaces | 103 | | Calogero F. — Variable phase approach to potential scattering | 3ff, 121 | | Bransden B., Joachain C. — Physics of Atoms and Molecules | 467 | | McGuire J.H. — Electron correlation dynamics in atomic collisions | 28, 35, 179, 198 | | Atkins P.W., Friedman R.S. — Molecular Quantum Mechanics | 451 | | Ehrenreich H., Seitz F., Turnbull D. — Solid State Physics.Volume 26. | 28 | | Vafa C., Zaslow E. — Mirror symmetry | 692 | | Bates D.R. — Quantum Theory. I. Elements | 311 | | Authier A., Lagomarsino S., Tanner B. — X-ray and neutron dynamical diffraction | 66 | | Migdal A.B., Krainov V. — Approximation Methods in Quantum Mechanics | 19, 24 | | Brown L., Dresden M., Hoddeson L. — Pions to quarks: Particle physics in the 1950s | 111, 118, 145, 200, 682, 698, 701, 704 | | Constantinescu F., Magyari E. — Problems in quantum mechanics | 263 | | Rodberg L.S., Thaler R.M. — Introduction to the quantum theory of scattering | 7, 21, 32, 292—299 | | Breuer H.-P., Petruccione F. — The Theory of Open Quantum Systems | 239 | | Farina J.E.G. — Quantum theory of scattering processes | see "Amplitude" | | Cercignani C. — Rarefied Gas Dynamics | 209 | | Fetter A.L., Walecka J.D. — Quantum theory of many-particle systems | 128—130, 143—146, 314 | | Brandt S., Dahmen H.D. — Quantum mechanics on the personal computer | 143, 152 | | Liboff R.L. — Introductory quantum mechanics | 607 | | De Witt L. Sumners — New Scientific Applications of Geometry and Topology (Proceedings of Symposia in Applied Mathematics, V. 45) | 195 |
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