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Differential geometry and general relativity with algebraifolds (2403.06548v2)

Published 11 Mar 2024 in math.DG, gr-qc, math-ph, and math.MP

Abstract: It is often noted that many of the basic concepts of differential geometry, such as the definition of connection, are purely algebraic in nature. Here, we review and extend existing work on fully algebraic formulations of differential geometry which eliminate the need for an underlying manifold. While the literature contains various independent approaches to this, we focus on one particular approach that we argue to be the most natural one based on the definition of "algebraifold", by which we mean a commutative algebra $\mathcal{A}$ for which the module of derivations of $\mathcal{A}$ is finitely generated projective. Over $\mathbb{R}$ as the base ring, this class of algebras includes the algebra $C\infty(M)$ of smooth functions on a manifold $M$, and similarly for analytic functions. An importantly different example is the Colombeau algebra of generalized functions on $M$, which makes distributional differential geometry an instance of our formalism. Another instance is a fibred version of smooth differential geometry, since any smooth submersion $M \to N$ makes $C\infty(M)$ into an algebraifold with $C\infty(N)$ as the base ring. Over any field $k$ of characteristic zero, examples include the algebra of regular functions on a smooth affine variety as well as any function field. Our development of differential geometry in terms of algebraifolds comprises tensors, connections, curvature, geodesics and we briefly consider general relativity.

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References (68)
  1. Robert Geroch “Einstein algebras” In Comm. Math. Phys. 26, 1972, pp. 271–275
  2. Michał Heller “Algebraic foundations of the theory of differential spaces” Differential spaces and their applications (Pasierbiec, 1990) In Demonstratio Math. 24.3-4, 1991, pp. 349–364
  3. Michael Heller “Einstein algebras and general relativity” In Internat. J. Theoret. Phys. 31.2, 1992, pp. 277–288
  4. “Sheaves of Einstein algebras” In Internat. J. Theoret. Phys. 34.3, 1995, pp. 387–398
  5. Anastasios Mallios “Geometry of vector sheaves. Vol. I” An axiomatic approach to differential geometry, Vector sheaves. General theory 439, Mathematics and its Applications Kluwer Academic Publishers, Dordrecht, 1998, pp. xx+441
  6. Anastasios Mallios “Geometry of vector sheaves. Vol. II” An axiomatic approach to differential geometry, Geometry. Examples and applications 439, Mathematics and its Applications Kluwer Academic Publishers, Dordrecht, 1998, pp. xxiv+436
  7. Anastasios Mallios “𝒜𝒜\mathscr{A}script_A-invariance: an axiomatic approach to quantum relativity” In Internat. J. Theoret. Phys. 47.7, 2008, pp. 1929–1948
  8. “Finitary, causal, and quantal vacuum Einstein gravity” In Internat. J. Theoret. Phys. 42.7, 2003, pp. 1479–1619
  9. Rene Schmidt “Arithmetic gravity and Yang-Mills theory: An approach to adelic physics via algebraic spaces” arXiv:0809.3579, 2008
  10. Edwin J. Beggs and Shahn Majid “Quantum Riemannian geometry” 355, Grundlehren der mathematischen Wissenschaften [Fundamental Principles of Mathematical Sciences] Springer, Cham, [2020] ©2020, pp. xvi+809
  11. Victor Pessers “Extensions of submanifold theory to non-real settings, with applications” arXiv:1801.00347, 2016
  12. Victor Pessers and Joeri Van der Veken “Riemannian manifolds as Lie-Rinehart algebras” In Int. J. Geom. Methods Mod. Phys. 13, 2016, pp. 1641003\bibrangessep23
  13. Gennady Sardanashvily “Lectures on Differential Geometry of Modules and Rings” arXiv:0910.1515, 2009
  14. Alexandre M. Vinogradov “Cohomological analysis of partial differential equations and secondary calculus” Translated from the Russian manuscript by Joseph Krasil’shchik 204, Translations of Mathematical Monographs American Mathematical Society, Providence, RI, 2001, pp. xvi+247
  15. Michel Dubois-Violette “Lectures on graded differential algebras and noncommutative geometry” arXiv:math/9912017 In Noncommutative differential geometry and its applications to physics (Shonan, 1999) 23, Math. Phys. Stud. Kluwer Acad. Publ., Dordrecht, 2001, pp. 245–306
  16. John Earman “World enough and space-time” Absolute versus relational theories of space and time, A Bradford Book MIT Press, Cambridge, MA, 1989, pp. xvi+233
  17. Jonathan Bain “Einstein algebras and the hole argument” PSA 2002. Part I In Philos. Sci. 70.5, 2003, pp. 1073–1085
  18. Robert Rynasiewicz “Rings, holes and substantivalism: on the program of Leibniz algebras” In Philos. Sci. 59.4, 1992, pp. 572–589
  19. Sarita Rosenstock, Thomas William Barrett and James Owen Weatherall “On Einstein algebras and relativistic spacetimes” arXiv:1506.00124 In Stud. Hist. Philos. Sci. B Stud. Hist. Philos. Modern Phys. 52, 2015, pp. 309–316
  20. “Structured spaces and their application to relativistic physics” In J. Math. Phys. 36.7, 1995, pp. 3644–3662
  21. Anastasios Mallios and Elemér E. Rosinger “Abstract differential geometry, differential algebras of generalized functions, and de Rham cohomology” In Acta Appl. Math. 55.3, 1999, pp. 231–250
  22. Yuri I. Manin “Reflections on arithmetical physics” In Conformal invariance and string theory (Poiana Braşov, 1987), Perspect. Phys. Academic Press, Boston, MA, 1989, pp. 293–303
  23. “Quantum geodesic flows and curvature” arXiv:2201.08244 In Lett. Math. Phys. 113.3, 2023, pp. Paper No. 73\bibrangessep44
  24. Edwin J. Beggs and Shahn Majid “Quantum geodesic flow on the integer lattice line” arXiv:2309.15102
  25. Edwin J. Beggs and Shahn Majid “Quantum geodesic flows on graphs” arXiv:2312.10779
  26. Johannes Huebschmann “Duality for Lie-Rinehart algebras and the modular class” arXiv:dg-ga/9702008 In J. Reine Angew. Math. 510, 1999, pp. 103–159
  27. Jeffrey M. Lee “Manifolds and differential geometry” 107, Grad. Stud. Math. American Mathematical Society, 2009
  28. Serge Lang “Differential and Riemannian manifolds” 160, Graduate Texts in Mathematics Springer-Verlag, New York, 1995, pp. xiv+364
  29. Georges Rham “Differentiable manifolds. Forms, currents, harmonic forms. Transl. from the French by F. R. Smith. Introduction to the English ed. by S. S. Chern” 266, Grundlehren Math. Wiss. Springer, 1984
  30. Francisco Gómez “The number of generators of the algebra of Kähler differentials” In Demonstratio Math. 23.2, 1990, pp. 375–383
  31. Howard Osborn “Derivations of commutative algebras” In Illinois J. Math. 13, 1969, pp. 137–144
  32. Jet Nestruev “Smooth manifolds and observables” Joint work of A. M. Astashov, A. B. Bocharov, S. V. Duzhin, A. B. Sossinsky, A. M. Vinogradov and M. M. Vinogradov. Translated from the 2000 Russian edition by Sossinsky, I. S. Krasil’schik and Duzhin 220, Graduate Texts in Mathematics Springer-Verlag, New York, 2003
  33. Emily Riehl “Category theory in context” math.jhu.edu/∼similar-to\sim∼eriehl/context.pdf Dover Publications, 2016
  34. Johannes Huebschmann “On the history of Lie brackets, crossed modules, and Lie-Rinehart algebras” arXiv:2208.02539 In J. Geom. Mech. 13.3, 2021, pp. 385–402
  35. Melvin Hochster “The Zariski-Lipman conjecture in the graded case” In J. Algebra 47.2, 1977, pp. 411–424
  36. John C. McConnell and J.Chris Robson “Noncommutative Noetherian rings” With the cooperation of L. W. Small 30, Graduate Studies in Mathematics American Mathematical Society, Providence, RI, 2001, pp. xx+636
  37. “The Lipman-Zariski conjecture in genus one higher” arXiv:1901.06009 In Forum Math. Sigma 8, 2020, pp. Paper No. e21\bibrangessep16
  38. Carl Tipler “The Zariski-Lipman conjecture for toric varieties” arXiv:2201.02109 In J. Algebra 609, 2022, pp. 547–551
  39. Qing Liu “Algebraic geometry and arithmetic curves” Translated from the French by Reinie Erné, Oxford Science Publications 6, Oxford Graduate Texts in Mathematics Oxford University Press, Oxford, 2002
  40. Raymond G.M. Brummelhuis and Peter J. Paepe “Derivations on algebras of holomorphic functions” In Nederl. Akad. Wetensch. Indag. Math. 51.3, 1989, pp. 237–242
  41. Joseph A. Becker and William R. Zame “Homomorphisms into analytic rings” In Amer. J. Math. 101.5, 1979, pp. 1103–1122
  42. Janusz Grabowski “Derivations of the Lie algebras of analytic vector fields” In Compositio Math. 43.2, 1981, pp. 239–252
  43. Satoshi Suzuki “Some types of derivations and their applications to field theory” In J. Math. Kyoto Univ. 21, 1981, pp. 375–382
  44. “Geometric theory of generalized functions with applications to general relativity” 537, Mathematics and its Applications Kluwer Academic Publishers, Dordrecht, 2001, pp. xvi+505
  45. Jean-François Colombeau “New generalized functions and multiplication of distributions” Notas de Matemática, 90. [Mathematical Notes] 84, North-Holland Mathematics Studies North-Holland Publishing Co., Amsterdam, 1984, pp. xii+375
  46. Jean-François Colombeau “Elementary introduction to new generalized functions” Notes on Pure Mathematics, 103 113, North-Holland Mathematics Studies North-Holland Publishing Co., Amsterdam, 1985, pp. xiii+281
  47. “Intrinsic definition of the Colombeau algebra of generalized functions” In Anal. Math. 17.2, 1991, pp. 75–132
  48. “Colombeau algebras on a C∞superscript𝐶C^{\infty}italic_C start_POSTSUPERSCRIPT ∞ end_POSTSUPERSCRIPT-manifold” In Indag. Math. (N.S.) 2.3, 1991, pp. 341–358
  49. “Foundations of a nonlinear distributional geometry” arXiv:math/0102019 In Acta Appl. Math. 71.2, 2002, pp. 179–206
  50. “Algebras of generalized functions with smooth parameter dependence” In Proc. Edinb. Math. Soc. (2) 55.1, 2012, pp. 105–124
  51. Lawrence Conlon “Differentiable manifolds”, Modern Birkhäuser Classics Birkhäuser Boston, Inc., Boston, MA, 2008, pp. xiv+418
  52. Akira Hattori “Rank element of a projective module” projecteuclid.org/euclid.nmj/1118801428 In Nagoya Math. J. 25, 1965, pp. 113–120
  53. “Connections in classical and quantum field theory” World Scientific Publishing Co., River Edge, NJ, 2000, pp. x+504
  54. Albrecht Pfister “Quadratic forms with applications to algebraic geometry and topology” 217, London Mathematical Society Lecture Note Series Cambridge University Press, Cambridge, 1995
  55. “Nonnegative functions as squares or sums of squares” In J. Funct. Anal. 232.1, 2006, pp. 137–147
  56. Murray Marshall “Positive polynomials and sums of squares” 146, Mathematical Surveys and Monographs American Mathematical Society, Providence, RI, 2008, pp. xii+187
  57. Ivan Kolář, Peter W. Michor and Jan Slovák “Natural operations in differential geometry” Springer-Verlag, Berlin, 1993, pp. vi+434
  58. “From calculus to cohomology” de Rham cohomology and characteristic classes Cambridge University Press, Cambridge, 1997, pp. viii+286
  59. Lyle Eugene Pursell “Algebraic Structures Associated With Smooth Manifolds” proquest.com/docview/2327629257, 1952
  60. John C. Baez and Michael Shulman “Lectures on n𝑛nitalic_n-categories and cohomology” arXiv:math/0608420 In Towards higher categories Springer, 2010, pp. 1–68
  61. Gerd Kainz, Andreas Kriegl and Peter W. Michor “C∞superscript𝐶C^{\infty}italic_C start_POSTSUPERSCRIPT ∞ end_POSTSUPERSCRIPT-algebras from the functional analytic viewpoint” In J. Pure Appl. Algebra 46.1, 1987, pp. 89–107
  62. Peter W. Michor and Jiří Vanžura “Characterizing algebras of C∞superscript𝐶C^{\infty}italic_C start_POSTSUPERSCRIPT ∞ end_POSTSUPERSCRIPT-functions on manifolds” arXiv:math/9404228 In Comment. Math. Univ. Carolin. 37.3, 1996, pp. 519–521
  63. Saeid Azam “Derivations of tensor product algebras” arXiv:0504368 In Commun. Algebra 36.3, 2008, pp. 905–927
  64. Robert M. Wald “General relativity” University of Chicago Press, Chicago, IL, 1984, pp. xiii+491
  65. Tsit-Yuen Lam “Lectures on modules and rings” 189, Graduate Texts in Mathematics Springer-Verlag, New York, 1999, pp. xxiv+557
  66. “Duality, trace, and transfer” maths.ed.ac.uk/ aar/papers /doldpup2.pdf In Proceedings of the International Conference on Geometric Topology (Warsaw, 1978) PWN, Warsaw, 1980, pp. 81–102
  67. “Traces in symmetric monoidal categories” arXiv:1107.6032 In Expo. Math. 32.3, 2014, pp. 248–273
  68. Peter Selinger “A survey of graphical languages for monoidal categories” In New structures for physics 813, Lecture Notes in Phys. Springer, Heidelberg, 2011, pp. 289–355
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