Types of quantum field thories
The intention of this page is to list a wide choice of main books and comprehensive reviews in mathematical physics. The irrelevant repetitions and minor, too specialized and obsolete books in any major respect should be avoided. We avoid references for quantum groups as they are many and the main ones can be found at the quantum group entry; similarly we avoided the relevant books on Kac-Moody algebras and groups but included the books on related VOAs and the Pressley-Segal book.
R. Courant, D. Hilbert, Methods of mathematical physics, 2 vols.
P. M. Morse, H. Feshbach, Methods of theoretical physics I, II, publisher
Michael Reed, Barry Simon, Methods of modern mathematical physics, 4 vols. (emphasis on functional analysis)
V. Vladimirov, Equations of mathematical physics, Moscow, Izdatel’stvo Nauka, (1976. 528 p. Russian; English edition, Mir 198x); Generalized functions in mathematical physics, Moscow
R. Abraham, J. Marsden, The Foundations of Mechanics, Benjamin Press, 1967, Addison-Wesley, 1978; large pdf 86 Mb free at CaltechAuthors
Anthony Sudbery, Quantum mechanics and the particles of nature: An outline for mathematicians
Brian C. Hall, Quantum theory for mathematicians, Springer GTM 267 (has also a big chapter on geometric quantization)
In addition to the geometrically written titles under classical mechanics above,
Peter Olver, Equivalence, invariants, and symmetry, Cambridge Univ. Press 1995; Applications of Lie groups to differential equations, Springer.
Shlomo Sternberg, Group theory and physics, Cambridge University Press 1994.
Klaas Landsman, Mathematical topics between classical and quantum mechanics, Springer Monographs in Mathematics 1998. xx+529 pp.
A. Cannas da Silva, A. Weinstein, Geometric models for noncommutative algebras, 1999, pdf
Global aspects of the geometry of spacetimes:
John K. Beem, Paul E. Ehrlich, Kevin L. Easley, Global Lorentzian geometry (ZMATH) (global aspects)
Arthur L. Besse, Einstein manifolds, Ergebnisse der Mathematik und ihrer Grenzgebiete, Band 10, Springer-Verlag, Berlin, Heidelberg, New York, London, Paris, Tokyo, 1987, xii + 510 pp. (differential geometry of solutions to Einstein equations, constant negative curvature, classification results, encyclopaedic; for a review see Bull. AMS
After the introduction emphasis on asymptotics of spacetimes far from gravitation objects:
Despite its title the next monograph does not just present the Kerr spacetime, it illustrates many core features of GR with the Kerr spacetime as the prominent example:
Here is an introduction to spinors in GR:
while the classic reference for this is:
Roger Penrose, Wolfgang Rindler, Spinors and spacetimes (2 vols, vol 1, ZMATH)
Eric Poisson, A relativist’s toolkit. The mathematics of black-hole mechanics. (ZMATH) (computationally oriented)
See also the above book by Ward and Wells; and mainstream theoretical physics gravity textbooks by Misner, Thorne and Wheeler; Schutz; Landau-Lifschitz vol. 2; Wald; Chandrasekhar etc. For the supergravity see the appropriate chapters in the above listed collection by Deligne et al. or the references listed at supergravity.
O. Babelon, D. Bernard, M. Talon, Introduction to classical integrable systems, Cambridge Univ. Press 2003.
T. Miwa, M. Jimbo, E. Date, Solitons: Differential equations, symmetries and infinite dimensional algebras, Cambridge Tracts in Mathematics 135, translated from Japanese by Miles Reid
V.E. Korepin, N. M. Bogoliubov, A. G. Izergin, Quantum inverse scattering method and correlation functions, Cambridge Univ. Press 1997.
Ludwig D. Faddeev, Leon Takhtajan, Hamiltonian methods in the theory of solitons, Springer
Yvonne Choquet-Bruhat, Cecile Dewitt-Morette, Analysis, manifolds and physics, 1982 and 2001
Albert Schwartz, Quantum field theory and topology, Grundlehren der Math. Wissen. 307, Springer 1993. (translated from Russian original)
Howard Georgi: Lie Algebras in Particle Physics. From isospin to unified theories. (ZMATH entry)
Eberhard Zeidler, Quantum field theory. A bridge between mathematicians and physicists. I: Basics in mathematics and physics. , II: Quantum electrodynamics
Charles Nash, Differential topology and quantum field theory, Acad. Press 1991.
P. Deligne, P. Etingof, D.S. Freed, L. Jeffrey, D. Kazhdan, J. Morgan, D.R. Morrison and E. Witten, eds. Quantum fields and strings, A course for mathematicians, 2 vols. Amer. Math. Soc. Providence 1999. (web version)
Gregory L. Naber, Topology, geometry, and gauge fields: interactions
Mikio Nakahara, Geometry, topology and physics
Marian Fecko, Differential geometry and Lie groups for physicists
V. S. Varadarajan, Supersymmetry for mathematicians: an introduction, AMS and Courant Institute, 2004.
R. S. Ward, R. O. Wells, Twistor geometry and field theory (CUP, 1990)
R. E. Borcherds, A. Barnard, Lectures on QFT, arxiv:math-ph/0204014
Paul Aspinwall, Tom Bridgeland, Alastair Craw, Michael R. Douglas, Mark Gross, Dirichlet branes and mirror symmetry, Amer. Math. Soc. Clay Math. Institute 2009.
Hisham Sati, Geometric and topological structures related to M-branes, part I (arXiv:1001.5020), part II: Twisted and structures (arxiv/1007.5419); part III: Twisted higher structures (http://arxiv.org/abs/1008.1755)
A. N. Kapustin, D. O. Orlov, Lectures on mirror symmetry, derived categories, and -branes, Russian Mathematical Surveys, 2004, 59:5, 907–940 (Russian version: pdf, [arxiv version: arxiv:math.AG/0308173).]
Martin Schottenloher, A mathematical introduction to conformal field theory (CFT on the plane)
Philippe Di Francesco, Pierre Mathieu, David Sénéchal, Conformal field theory, Springer 1997 (comprehensive textbook for theoretical physicists)
Ralph Blumenhagen, Erik Plauschinn, Introduction to conformal field theory: with applications to string theory, Springer Lecture Notes in Physics (2011)
V. Kac, Vertex algebras for beginners, Amer. Math. Soc.
B. Bakalov, A. Kirillov, Lectures on tensor categories and modular functors, AMS, University Lecture Series, (2000) (web)
The related subject of positive energy representations for loop groups is represented in unavoidable reference
N. N. Bogoliubov, A. A. Logunov, I. T. Todorov, Introduction to axiomatic quantum field theory, 1975
Huzihiro Araki: Mathematical theory of quantum fields. Oxford University Press 1999 ZMATH entry.
James Glimm, Arthur Jaffe, Quantum physics: a functional integral point of view, Springer
Sergio Albeverio, Jens Erik Fenstad, Raphael Hoegh-Krohn, Nonstandard methods in stochastic analysis and mathematical physics, Acad. Press 1986 (there is also a Dover 2009 edition, and a 1990 Russian translation)
http://en.wikibooks.org/wiki/Introduction_to_Mathematical_Physics/References (that list has mostly references in the area of theoretical physics and just a minority with rigor of mainstream mathematical physics)
www.stringwiki.org – wiki contains entries on several dozens of string theory related topics, where each entry has several references, mainly papers available online
Mathematical Foundations of Quantum Field and Perturbative String Theory, Proceedings of Symposia in Pure Mathematics 83, Amer. Math. Soc. (2011)
reference list of Movshev’s sunysb course on QM
John Baez: How to Learn Math and Physics (here)
various lectures notes in mathematical physics, Ulrich Theis’ list at Jena