| Книга | Страницы для поиска |
| Wolf E.L. - Nanophysics and nanotechnology. An introduction to modern concepts in nanoscience | |
| Taylor M.E. - Partial Differential Equations. Basic theory (vol. 1) | 59, 91 |
| Taylor M.E. - Partial Differential Equations. Qualitative studies of linear equations (vol. 2) | 119 |
| Heinbockel J.H. - Introduction to tensor calculus and continuum mechanics | 218, 287 |
| Ito K. - Encyclopedic Dictionary of Mathematics. Vol. 2 | 258.D 271.E |
| Grimaldi R.P. - Discrete and combinatorial mathematics. An introduction | 43 |
| Zeidler E. - Nonlinear Functional Analysis and its Applications IV: Applications to Mathematical Physic | 32 |
| Collin R.E. - Foundations for Microwave Engineerings | 451 |
| Borisenko A.I., Tarapov I.E. - Vector and Tensor Analysis with Applications | 57 |
| Meirovitch L. - Methods of analytical dynamics | 12, 22 |
| Olver P.J. - Equivalence, Invariants and Symmetry | 242 |
| Cahn R.N. - Semi-Simple Lie Algebras and Their Representations | 7, 79 |
| Schweizer W. - Numerical quantum dynamics | 9 |
| Palen S. - Schaum's Outline of Astronomy | 4 |
| Felsager B. - Geometry, particles and fields | 28 |
| Zienkiewicz O.C., Taylor L.R. - The finite element method (vol. 2, Solid mechanics) | 399 |
| Goldstein H., Poole C., Safko J. - Classical mechanics | 4-vector, 310 |
| Atkins P.W., Friedman R.S. - Molecular Quantum Mechanics | 73, 79 |
| Sadd M.H. - Elasticity: theory, applications, and numerics | 60 |
| Williamson R.E., Crowell R.H., Trotter H.F. - Calculus of vector functions | 121 |
| Mukamel S. - Principles of Nonlinear Optical Spectroscopy | 21 |
| Ohnuki Y. - Unitary representations of the Poincare group and relativistic wave equations | 63, 72 |
| Debnath L., Mikusinski P. - Introduction to Hilbert Spaces with Applications | 344, 353 |
| Maugin G.A. - Material inhomogeneities in elasticity | 10, 86 |
| Hand L.N., Finch J.D. - Analytical Mechanics | 137-139, 170-172, 283, 245 (prob) |
| Dyke Ph.P.G. - Managing Mathematical Projects - with Success! | 47 |
| Hogben L. - Handbook of Linear Algebra | 59-9 to 59-10 |
| Shafarevich I.R., Kostrikin A.I. (ed.) - Basic Notions of Algebra | 98, 198, 242 |
| Reid M., Szendroi B. - Geometry and Topology | 93, 154 |
| Atiyah M. - Representation Theory of Lie Groups | 158 |
| Strauss W.A. - Partial Differential Equations: An Introduction | 279-282 |
| Roman P. - Introduction to quantum field theory | 71 |
| Krupkova O. - The Geometry of Ordinary Variational Equations | 159 |
| Mayer J.E., Mayer M.G. - Statistical Mechanics | see 'Momenta' |
| Weatherburn C. - Advanced Vector Analysis | 77 |
| Bridges Th.J., Furter J.E. - Singularity Theory and Equivariant Symplectic Maps | 136 |
| Raabe D. - Computational materials science | 95 |
| Greiner W. - Quantum mechanics. An introduction | 5, 81 |
| Maugin G.A. - Nonlinear waves in elastic crystals | 66 |
| Thaller B. - Visual quantum mechanics | 92, 125, 216, 221, 224 |
| O'Donnel P. - Introduction to 2-Spinors in General Relativity | 171 |
| Hall B.C. - Lie Groups, Lie Algebras, and Representations: An Elementary Understanding | 101, 329 |
| Greiner W. - Classical mechanics. Point particles and relativity | 149, 153 |
| Gudder S.P. - Stochastic methods in quantum mechanics | 4 |
| Heusler M., Goddard P. - Black Hole Uniqueness Theorems | 25 |
| Thouless D.J. - Topological quantum numbers in nonrelativistic physics | 3, 4, 27, 55 57, 63, 64, 81, 87 |
| Reed M., Simon B. - Methods of Modern mathematical physics (vol. 4) Analysis of operators | 90 |
| Walecka J.D. - Fundamentals of statistical mechanics | 166, 202, 217 |
| Chaikin P.M., Lubensky T.C. - Principles of condensed matter physics | 420, 425, 441 |
| Born M. - Natural philosophy of cause and chance (The Waynflete lectures) | 86, 111, 182, 184 |
| Arnold V.I., Khesin B.A. - Topological methods in hydrodynamics | 15, 50 |
| Feynman R.P., Leighton R.B., Sands M. - The Feynman lectures on physics (vol.1) | 7-7, 18-5 f, 20-1 |
| Ziman J.M. - Elements of Advanced Quantum Theory | see also 'Spin' |
| Frank J., King A., Raine D.J. - Accretion Power in Astrophysics | 226, 227, 229, 231, 233, 236, 246, 285, 289 |
| Griffits D.J. - Introduction to quantum mechanics | 16, 145-153 |
| Szekeres P. - A Course in Modern Mathematical Physics: Groups, Hilbert Space and Differential Geometry | 378 |
| Cantwell B.J., Crighton D.G. (Ed), Ablowitz M.J. (Ed) - Introduction to Symmetry Analysis | 111, 506, 507 |
| Lin C.C., Segel L.A. - Mathematics Applied to Deterministic Problems in the Natural Sciences | 466 |
| Lerner K.L., Lerner B.W. - The gale encyclopedia of science (Vol. 6) | 2:1020-1021, 2:1021t, 3:1899, 5:3703 |
| Elberly D.H., Shoemake K. - Game Physics | 43-44, 225 |
| McDuff D., Salamon D. - Introduction to Symplectic Topology | 25 |
| Ito K. - Encyclopedic Dictionary of Mathematics | 258.D, 271.E |
| Menzel D.H. - Mathematical Physics | 8, 30, 68 |
| Polkinghorne J.C. - The quantum world | 11, 13, 84, 92 |
| Eddington A. - Relativity Theory of Protons and Electrons | 122 |
| Dirac P.A.M. - The Principles of Quantum Mechanics | 140 |
| Jauch J.M. - Foundations of quantum mechanics | 228 |
| Mukamel S. - Principles of nonlinear spectroscopy | 21 |
| Zajac A. - Optics | 330 |
| Schroeder M.R. - Schroeder, Self Similarity: Chaos, Fractals, Power Laws | 66 |
| Thaller B. - The Dirac equation | 8, 22, 124 |
| Sokolnikoff I.S. - Mathematics of Physics and Modern Engineering | 305 |
| Fishbane P.M. - Physics For Scientists and Engineers with Modern Physics | 265 |
| Bethe H.A., Jackiw R. - Intermediate Quantum Mechanics | 12 |
| Audin M. - Spinning Tops: A Course on Integrable Systems | 16, 41 |
| Born M. - Atomic Physics | 320 |
| De Felice F., Clarke C.J.S. - Relativity on curved manifolds | see "Momentum" |
| Kyle T.G. - Atmospheric transmission, emission and scattering | 160, 168, 181, 186, 192 |
| Nikiforov A.F., Uvarov V. - Special Functions of Mathematical Physics: A Unified Introduction with Applications | xiii, 81 |
| Heitler W. - Elementary Wave Mechanics With Applications to Quantum Chemistry | 50 |
| Greiner W., Muller B. - Gauge theory of weak interactions | 92, 100ff, 214, 262 |
| Forsythe W.E. - Smithsonian Physical Tables | 4 |
| Strichartz R.S. - The way of analysis | 508 |
| Tung W.K. - Group Theory in Physics: An Introduction to Symmetry Principles, Group Representations, and Special Functions | 102 105, 217 |
| Yulsman T. - Origins. The quest for our cosmic roots | 231, 249-250, 261-267, 295-296 |
| Fulling S. - Aspects of Quantum Field Theory in Curved Spacetime | 52, 54, 224, 242, 258-263, 266, 268-269, 279-280 (see also 'Spin') |
| Adair R.K. - The Great Design: Particles, Fields, and Creation | 16-22, 26-28, 140 |
| Feynman R.P., Leighton R.B., Sands M. - The Feynman lectures on physics (vol.2) | I-7-7, I-18-5 f, I-20-1 |
| Lopuzanski J. - An introduction to symmetry and supersymmetry in quantum field theory | 78 |
| Peleg Y., Pnini R., Zaarur E. - Schaum's outline of theory and problems of quantum mechanics | 98 |
| Ardema M.D. - Newton-Euler Dynamics | 166, 195 |
| Dubrovin B.A., Fomenko A.T. - Modern Geometry - Methods and Applications: The Geometry of Surfaces, Transformation Groups and Fields | 333, 336, 387 |
| Allen H.S. - Electrons and Waves | 45, 211-212, 228, 275, 279-280, 299 |
| Nayfeh M.H., Brussel M.K. - Electricity and Magnetism | 287 |
| Kleppner D., Kolenkow R. - An introduction to mechanics | 233ff. |
| Hughston L.P., Tod K.P., Bruce J.W. - An Introduction to General Relativity | 44, 135, 142 |
| Ludvigsen M. - General relativity. A geometric approach | 74, 125, 131 |
| Dirac P.A.M. - The Principles of Quantum Mechanics, Vol. 27 | 140 |
| O'Raifeartaigh L. - Group Structure of Gauge Theories | 13 |
| Schiff L.I. - Quantum mechanics | 74-75 |
| Visser M. - Lorentzian wormholes. From Einstein to Hawking | 75, 79, 328 |
| Englert B.G. (Ed) - Quantum Mechanics | 151, 183, 200 |
| Walker J. - The flying circus of physics: with answers | 2.40, 2.41, 2.44-2.49, 2.51, 2.56.2.58, 2.69-2.73, 4.54, 4.67 |
| Meyerhof W.E. - Elements of Nuclear Physics | see also 'Spin' |
| Collins P.D., Squires E.J., Martin A.D. - Particle Physics and Cosmology | 223, 328 |
| Love A.E. - Theoretical Mechanics, an Introductory Treatise on the Principles of Dynamics: With Applications and Numerous Examples | 145 |
| Callaghan P. - Principles of Nuclear Magnetic Resonance Microscopy | 21, 28-30 |
| Cercignani C. - Theory and Application of the Boltzman Equation | 27, 67, 68 |
| Birrell N.D., Davies P.C.W. - Quantum Fields in Curved Space | 18, 82 |
| Griffits D. - Introduction to elementary particles | 13 |
| Beltrametti E.G., Cassinelli G. - The Logic of Quantum Mechanics (Encyclopedia of Mathematics and Its Applications - Vol 15) | 30, 42 |
| Bogolubov N.N., Logunov A.A., Todorov I.T. - Introduction to Axiomatic Quantum Field Theory | 110, 143-144, 146 (see also 'Spin', 'Poincare group', 'Lie algebra') |
| Cohen-Tannoudji C., Dupont-Roc J., Grynberg G. - Photons and atoms: introduction to quantum electrodynamic | (see also 'Multipole, expansion's) |
| Wolf E.L. - Nanophysics and nanotechnology: an introduction to modern concepts in nanoscience | 68 |
| Bjorken J.D., Drell S.D. - Relativistic Quantum Fields | 19, 55 |
| Park D. - Introduction to the quantum theory | 45, 81, 157-167, 632 |
| Mason G.W., Griffen D.T., Merrill J. - Physical Science Concepts | 55-57, 62-64, 264-265, 269, 275-276, 382 |
| Fetter A.L., Walecka J.D. - Quantum theory of many-particle systems | 344, 504, 511p |
| Douglas Clark C.H. - The basis of modern atomic theory | 179-80, 183, 187, 190-1 |
| Avery J. - Creation and Annihilation Operators | 53, 54, 56, 68, 74, 75, 81, 83, 155, 158, 190 |
| Stahl A. - Physics with tau leptons | 53, 54, 56, 68, 74, 75, 81, 83, 155, 158, 190 |
| Streetman B.G. - Solid State Electronic Devices | 33 |
| Collins P.D.B., Martin A.D., Squires E.J. - Particle Physics and Cosmology | 223, 328 |
| Carrol B.W., Ostlie D.A. - An introduction to modern astrophysics | 43, 133 |
| Kompaneyets A.S., Yankovsky G. - Theoretical Physics | 36 |
| Slater J.C. - Quantum Theory of Atomic Structure vol1 | 23-27, 177-182, 245-264, 484-485 |
| Butcher J. - Numerical Methods for Ordinary Differential Equations | 5 |
| D'Inverno R. - Introducing Einstein's Relatvity | 193, 253, 254, 256, 263, 266 |
| Truesdell C., Noll W. - The Non-Linear Field Theories Of Mechanics | 40 |
| Cherrington B.E. - Gaseous Electronics and Gas Lasers | 25 |
| Halzen F., Martin A.D. - Quarks and Leptons: An Introductory Course in Modern Particle Physics | 37 |
| Bates D.R. - Quantum Theory | 49, 102 |
| Daniel C. Mattis - The theory of magnetism made simple: an introduction to physical concepts and to some useful mathematical methods | 31, 54, 56, 69-103, 108, 111, 125-127, 130, 131, 138, 162, 177, 233, 235, 238, 261, 293, 296, 435 |
| Greiner W., Mueller B. - Quantum mechanics: symmetries | 44 |
| Lawden D.F. - An Introduction to Tensor Calculus, Relativity and Cosmology | 57 |
| Gilmore R. - Lie Groups, Lie Algebras and Some of Their Applications | 253, 424, 425 |
| de Groot S.R., Mazur P. - Non-equilibrium thermodynamics | 304-305 |
| Hume-Rothery W., Raynor G.V. - The Structure of Metals and Alloys | 5 |
| Hume-Rothery W. - Atomic Theory for Students of Metallurgy | 14, 51, 62, 125 |
| Tomotada O. - Quantum invariants: a study of knots, 3-manifolds, and their sets | 63, 72 |
| Houston W.V. - Principles of Mathematical Physics | 20 |
| Weissbluth M. - Atoms and Molecules | see also Orbital angular momentum; Spin |
| Montenbruck O. - Practical Ephemeris Calculations | 65, 104 |
| Weyl H. - Space, Time, Matter | 46 |
| Oprea J. - Differential Geometry and Its Applications | 223 |
| Cotterill R.M.J. - Biophysics: An Introduction | 94 |
| Basdevant J.-L., Dalibard J. - Quantum Mechanics | 189 |
| Murrel J.N., Bosanac S.D. - Introduction to the Theory of Atomic and Molecular Collisions | 19 |
| Slater J.C., Frank N.H. - Mechanics | 56, 73 |
| Christensen S.M. - Quantum theory of gravity | 148, 154 |
| Margenau H., Murphy G.M. - The mathematics of physics and chemistry | 285 |
| Bayin S.S. - Mathematical Methods in Science and Engineering | 116 |
| Woodhouse N.M.J. - Geometric quantization | 45, 114, 177, 235 |
| Arya A.P. - Introduction to Classical Mechanics | 510 |
| Thompson Philip A. - Compressible-fluid dynamics | 18n. |
| Carmeli M. - Classical Fields: General Gravity and Gauge Theory | 210, 212, 217, 250-251, 330, 384 |
| Staicu V. (ed.) - Differential Equations, Chaos and Variational Problems | see "Spin angular momentum" |
| Landau L.D., Lifshitz E.M. - The classical theory of fields | 42, 84 |
| Kimball A.I. - A college textbook of physics | 93 |
| Baez J.C., Muniain J.P. - Gauge theories, knots, and gravity | 197 |
| Corson E.M. - Perturbation Methods in the Quantum Mechanics of N-Electron Systems | 42 |
| Truesdell C.A., Wang C.C. - Rational Thermodynamics | See "Momentum" |
| Kleinert H. - Gauge fields in condensed matter (part 4) | 1240, 1380 |
| Messiah A. - Quantum mechanics. Volume 1 | see Momentum |
| Novikov S.P., Fomenko A.T. - Basic elements of differential geometry and topology | 366 |
| Heisenberg W.K. - Nuclear Physics | 55 |
| Wilson E.B. - Molecular Vibrations. The Theory of Infrared and Raman Vibrational Spectra | 277 |
| Mott N.F., Sneddon I.N. - Wave Mechanics and Its Applications | 44, 85, 86, 305, 306, 359-62 |
| Heisenberg W. - Nuclear physics | 55 |
| Hermann R. - Differential geometry and the calculus of variations | 100, 109 |
| Gallavotti G. - Statistical Mechanics | 13 |
| Riley, Hobson - Mathematical Methods for Physics and Engineering | 782, 798 |
| Selig J.M. - Introductory robotics | 96, 97-98, 102 |
| Knight J. - Science of everyday things (volume 4). Real-life earth science | see also "Conservation of angular momentum", "Momentum" |
| Umezawa H. - Quantum Field Theory | 100, 105, 176 |
| Barnett S.M., Radmore P.M. - Methods in Theoretical Quantum Optics | 35, 36, 80, 81 |
| Rosser J.B., Newton R.R., Gross G.L. - Mathematical Theory of Rocket Flight | 13 |
| Lipkin H.J. - Lie Groups for Pedestrians | 2 |
| Shu F.H. - The Physical Universe: An Introduction to Astronomy | 47-50, 134, 281, 475 |
| Mayer J.E., Goeppert Mayer M. - Statistical mechanics | see "Momenta" |
| Beard D.B. - Quantum Mechanics | 129-136 |
| Atkins P. - Molecular Quantum Mechanics | 73, 79 |
| Nelson E.W., Best C.L., McLean W.G. - Schaum's outline of theory and problems of engineering mechanics. Statics and dynamics | see "Moment of momentum" |
| Amoroso R.L. (ed.), Hunter G. (ed.), Vigier J.-P. (ed.) - Gravitation and Cosmology: From the Hubble Radius to the Planck Scale | 245, 254, 350 |
| Meijer P.H.E. - Group Theory: The Application to Quantum Mechanics | 34, 142, 259 |
| Wilson W. - Theoretical physics - Relativity and quantum dynamics | 241 |
| Scarborough J.B. - The gyroscope: Theory and applications | 26 |
| Kemble E. C. - The fundamental principles of quantum mechanics | 151, 224-234, 314, 317 |
| Bethe H.A. - Elementary nuclear theory | 38 |
| Haar D. - Selected problems in quantum mechanics | section 4 |
| Achmanov S.A., Nikitin S.Yu. - Physical Optics | 60 |
| Jauch J.M. - Foundations Of Quantum Mechanics | 228 |
| Dirac P.A.M. - The Principles of Quantum Mechanics | 140 |
| Chaikin P., Lubensky T. - Principles of condensed matter physics | 420, 425, 441 |
| Henley E.M., Thirring W. - Elementary Quantum Field Theory | 34-40, 260 |
| Carroll R.W. - Mathematical physics | 64 |
| Richards P.I. - Manual of Mathematical Physics | 6, 131 |
| Podgorsak E. - Radiation Physics for Medical Physicists | 407 |
| Wolfgang K. H. Panofsky, Phillips Panofsky, Melba Panofsky - Classical Electricity and Magnetism | 130, 133, 269, 270, 431, 437 |
| Brewer D.F. - Progress in Low Temperature Physics. Volume X | 156 |
| Thaller B. - The Dirac equation | 8, 22, 124 |
| Hugh D. Young, Roger A. Freedman - University physics with modern physics | 977-978 |
| Loomis L.H., Sternberg S. - Advanced calculus | 523 |
| Luenberger D.G. - Introduction to dynamic systems | 389 |
| Lane S.M. - Mathematics, form and function | 262 |
| Tenenbaum M., Pollard H. - Ordinary differential equations: an elementary textbook for students of mathematics, engineering, and the sciences | 472 |
| Hirsch M.W., Smale S. - Differential Equations, Dynamical Systems, and Linear Algebra | 21 |
| Beard D.B. - Quantum Mechanics | 129-136 |
| Atkins P.W., Friedman R.S. - Molecular Quantum Mechanics | 73, 79 |
| Hobbie R., Roth B. - Intermediate Physics for Medicine and Biology, | 516 |
| Mandl F. - Quantum mechanics | 14, 25, see also "Spin" |
| Frankel T. - The geometry of physics: an introduction | 620 |
| Collins G.W. - The virial theorem in stellar astrophysics | 43, 57 |
| Truesdell C - Rational Thermodynamics | see "Momentum" |
| Griffits D.J. - Introductions to electrodynamics | 358-362 |
| Guyon E., Hulin J., Petit L. - Physical Hydrodynamics | 281-282 |
| Schutz B.F. - A first course in general relativity | 298, 317 |
| Amelino-Camelia G., Kowalski-Glikman J. - Planck Scale Effects in Astrophysics and Cosmology (Lecture Notes in Physics) | 293 |
| Penrose R., Rindler W. - Spinors and space-time. Spinor and twistor methods in space-time geometry | 68, 85 |
| Hademenos G.J. - Applied physics | 49 |
| Vafa C., Zaslow E. - Mirror symmetry | 282 |
| Synge J.L. - Relativity: The Special Theory | 216ff, 251ff, 312, 397, see also "Intrinsic angular momentum" |
| Bates D.R. - Quantum Theory. I. Elements | 49, 102 |
| Schiff L.I. - Quantum Mechanics | 81 |
| Adler S.L. - Quaternionic Quantum Mechanics and Quantum Fields | 53, 64-70, 75, 85, 166 |
| Barut A.O. - Electrodynamics and Classical Theory of Fields and Particles | 57, 129, 163 |
| Lifschitz A.E. - Magnetohydrodynamics and Spectral Theory | 114 |
| Greiner W. - Classical mechanics. Systems of particles and hamiltonian dynamics | 67 |
| Yariv A. - Quantum Electronics | 14, 31 |
| Zeidler E. - Oxford User's Guide to Mathematics | 432, 863 |
| Hassani S. - Mathematical Methods: for Students of Physics and Related Fields | 28 |
| Haile J.M. - Molecular Dyanmics Simualtion: Elementary Methods | 89-91 |
| Haile J.M. - Molecular Dyanmics Simualtion: Elementary Methods | 89-91 |
| Ridley B.K. - Quantum Processes in Semiconductors | 14 |
| Hume-Rothery W. - Electrons, Atoms, Metals and Alloys | 29 |
| Attwood S.S. - Electric and Magnetic Fields | 252 |
| Rice F.O., Teller E. - The structure of matter | 232, 239, 242, 245, 253 |
| Rodberg L.S., Thaler R.M. - Introduction to the quantum theory of scattering | 278-320 |
| Giles R. - Mathematical foundation of thermodynamics | 131, 170 |
| Glimm J., Jaffe A. - Quantum Physics: A Functional Integral Point of View | 8, 10, 25, 26, 31, 308, 309, 310, 315 |
| Akhmanov S.A., Nikitin S.Yu. - Physical Optics | 60 |
| Farina J.E.G. - Quantum theory of scattering processes | 11 |
| Johnson W.C. - Mathematical and physical principles of engineering analysis | 20-22 |
| Lyons L. - All You Wanted to Know about Mathematics but Were Afraid to Ask - Mathematics for Science Students. Volume 1 | 56-57, 140, 195, 315 |
| Thorne K.S., Hawking S. - Black holes and time warps: Einstein's outrageous legacy | 27 |
| Suter D. - The physics of laser-atom interactions | 131-137 |
| Prigogine I., Rice S. - Advances in Chemical Physics.Volume 18. | 183 |
| Close F. - The New Cosmic Onion: Quarks and the Nature of the Universe | 26, 83 |
| Frankel T. - The geometry of physics: An introduction | 620 |
| Sturrock P. - Plasma Physics: An Introduction to the Theory of Astrophysical, Geophysical and Laboratory Plasmas | 39 |
| Cercignani C. - Rarefied Gas Dynamics | 242, 243 |
| Feynman R., Leighton R., Sands M. - Lectures on Physics 2 | I-7-7, I-18-5 f, I-20-1 |
| Landau L.D., Lifshitz E.M. - Course of Theoretical Physics (vol.3). Quantum Mechanics. Non-relativistic Theory | 82ff |
| Greiner W., Maruhn J. - Nuclear models | 11-38, 359-361 |
| Davies P. - The New Physics | 210, 383, 386, 398, 403, 421, 465, see also "Spin", "Star formation, problems of" |
| Kleinert H. - Gauge fields in condensed matter (part 2) | 89, 90 |
| Sexl R., Urbantke H.K. - Relativity, Groups, Particles. Special Relativity and Relativistic Symmetry in Field and Particle Physics | 326 |
| Mackey G. - Unitary Group Representations in Physics, Probability and Number Theory | 172 |
| Guillemin V., Sternberg S. - Symplectic techniques in physics | 126, 128 |
| Collins P.D.B., Martin A.D., Squires E.J. - Particle Physics and Cosmology | 223, 328 |
| Blin-Stoyle R.J. - Eureka! Physics of particles, matter and the universe | 18 |
| Park D. - Introduction to the Quantum Theory (Pure & Applied Physics) | 45, 81, 157-167, 632 |
| Fetter A.L., Walecka J.D. - Quantum theory of many-particle systems | 344, 504, 577p |
| Mac Lane S. - Mathematics: Form and Function | 262 |
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