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Schrödinger symmetry: a historical review

Published 29 Mar 2024 in hep-th, cond-mat.stat-mech, gr-qc, math-ph, and math.MP | (2403.20316v3)

Abstract: This paper reviews the history of the conformal extension of Galilean symmetry, now called Schr\"odinger symmetry. In the physics literature, its discovery is commonly attributed to Jackiw, Niederer and Hagen (1972). However, Schr\"odinger symmetry has a much older ancestry: the associated conserved quantities were known to Jacobi in 1842/43 and its euclidean counterpart was discovered by Sophus Lie in 1881 in his studies of the heat equation. A convenient way to study Schr\"odinger symmetry is provided by a non-relativistic Kaluza-Klein-type "Bargmann" framework, first proposed by Eisenhart (1929), but then forgotten and re-discovered by Duval {\it et al.} only in 1984. Representations of Schr\"odinger symmetry differ by the value $z=2$ of the dynamical exponent from the value $z=1$ found in representations of relativistic conformal invariance. For generic values of $z$, whole families of new algebras exist, which for $z=2/\ell$ include the $\ell$-conformal galilean algebras. We also review the non-relativistic limit of conformal algebras and that this limit leads to the $1$-conformal galilean algebra and not to the Schr\"odinger algebra. The latter can be recovered in the Bargmann framework through reduction. A distinctive feature of Galilean and Schr\"odinger symmetries are the Bargmann super-selection rules, algebraically related to a central extension. An empirical consequence of this was known as "mass conservation" already to Lavoisier. As an illustration of these concepts, some applications to physical ageing in simple model systems are reviewed.

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References (150)
  1. J.D. Bjørken, “Asymptotic Sum Rules at Infinite Momentum”, Phys. Rev. 179, 1547 (1969).
  2. G. Altarelli, G. Parisi, “Asymptotic freedom in parton language”, Nucl. Phys. B126, 298 (1977).
  3. D.G. Boulware, L.S. Brown, R.D. Pecceci, “Deep-Inelastic Electroproduction and Conformal Symmetry”, Phys. Rev. D2, 293 (1970).
  4. A.A. Belavin, A.M. Polyakov, A.B. Zamolodchikov, “Infinite conformal symmetry in two-dimensional quantum field-theory”, Nucl. Phys. B241, 333 (1984).
  5. A.B. Zamolodchikov, “Integrable Field Theory from Conformal Field Theory”, Adv. Stud. Pure Math. 19, 641 (1989).
  6. J. Maldacena, “The Large-N𝑁Nitalic_N Limit of Superconformal Field Theories and Supergravity”, Int. J. Theor. Phys. 38, 1113 (1999), [arXiv:hep-th/9711200].
  7. O. Aharony, S. Gubser, J. Maldacena, H. Ooguri, Y. Oz, “Large-N𝑁Nitalic_N Field Theories, String Theory and Gravity”, Phys. Rep. 323, 183 (2000). [arXiv:hep-th/9905111].
  8. H. Bondi, M.G.J. van der Burg, A.W.K. Metzner, “Gravitational waves in general relativity”, Proc. R. Soc. Lond. A269, 21 (1962).
  9. R.K. Sachs, “Gravitational waves in general relativity VIII. Waves in asymptotically flat space-time”, Proc. R. Soc. Lond. A270, 103 (1962).
  10. G. Barnich and G. Compère, “Classical central extension for asymptotic symmetries at null infinity in three spacetime dimensions”, Class. Quant. Grav. 24 F15 (2007); corrigendum 24, 3139 (2007) [gr-qc/0610130].
  11. A. Bagchi, and R. Gopakumar, “Galilean Conformal Algebras and AdS/CFT,” JHEP 0907:037 (2009), [arXiv:0902.1385 [hep-th]].
  12. G. Barnich, A. Gomberoff, H.A. González, “Three-dimensional Bondi-Metzner-Sachs invariant two-dimensional field-theories as the flat limit of Liouville theory”, Phys. Rev. D87, 124032 (2007), [arxiv:1210.0731].
  13. J.D. Miller and K De’Bell, “Randomly branched polymers and conformal invariance”, J. Physique I3, 1717 (1993).
  14. V. Riva and J.L. Cardy, “Scale and conformal invariance in field theory: a physical counterexample”, Phys. Lett. B622, 339 (2005) [arxiv:hep-th/0504197].
  15. A. Gimenez-Grau, Y. Nakayama, S. Rychkov, “Scale without Conformal Invariance in Dipolar Ferromagnets” [arXiv:2309.02514].
  16. J. Polchinski, “Scale and conformal invariance in quantum field theory”, Nucl. Phys. B303, 226 (1988).
  17. D. Dorigoni and V. S. Rychkov, “Scale Invariance + Unitarity ⇒⇒\Rightarrow⇒ Conformal Invariance?”, [arXiv:0910.1087 [hep-th]].
  18. C. Duval, P. A. Horvathy and L. Palla, “Conformal Properties of Chern-Simons Vortices in External Fields,” Phys. Rev. D50, 6658 (1994) [arXiv:hep-th/9404047 [hep-th]].
  19. C. Duval, and P. A. Horváthy “Non-relativistic conformal symmetries and Newton-Cartan structures,” J. Phys. A42, 465206 (2009) [arXiv:0904.0531 [math-ph]].
  20. M. Henkel, “Phenomenology of local scale invariance: From conformal invariance to dynamical scaling,” Nucl. Phys. B641, 405 (2002) [arXiv:hep-th/0205256].
  21. C.G.J. Jacobi, “Vorlesungen über Dynamik.” Univ. Königsberg 1842-43. Herausg. A. Clebsch. Vierte Vorlesung: Das Prinzip der Erhaltung der lebendigen Kraft. Zweite Ausg. C. G. J. Jacobi’s Gesammelte Werke. Supplementband. Herausg. E. Lottner. Berlin Reimer (1884). A recent english translation is available as Jacobi’s Lectures on Dynamics, 2nd edition, Texts and Readings in Mathematics, https://doi.org/10.1007/978-93-86279-62-0, Hindustan Book Agency Gurgaon.
  22. S. Lie, “Über die Integration durch bestimmte Integrale von einer Klasse linearer partieller Differentialgleichungen,” Arch. Math. (Kristiania) 6, 328 (1881).
  23. L. P. Eisenhart, “Dynamical trajectories and geodesics”, Ann. of Math. 30, 591 (1929).
  24. P. Appell, “Sur l’équation ∂2z∂x2−∂z∂y=0superscript2𝑧superscript𝑥2𝑧𝑦0\frac{\partial^{2}z}{\partial x^{2}}-\frac{\partial z}{\partial y}=0divide start_ARG ∂ start_POSTSUPERSCRIPT 2 end_POSTSUPERSCRIPT italic_z end_ARG start_ARG ∂ italic_x start_POSTSUPERSCRIPT 2 end_POSTSUPERSCRIPT end_ARG - divide start_ARG ∂ italic_z end_ARG start_ARG ∂ italic_y end_ARG = 0 et la théorie de la chaleur”, J. Mathématiques Pures Appliquées, 4e𝑒{}^{e}start_FLOATSUPERSCRIPT italic_e end_FLOATSUPERSCRIPT série, 8, 187 (1892).
  25. J.A. Goff, “Transformations leaving invariant the heat equation of physics”, Amer. J. Math. 49, 117 (1927).
  26. L.V. Ovsiannikov, “Groups and group-invariant solutions of differential equations”, Dokl. Akad. Nauk SSSR 118, 439 (1958) (in russian).
  27. R. Jackiw, “Introducing scale symmetry”, Phys. Today 25 (1972) 23.
  28. U. Niederer, “The maximal kinematical invariance group of the free Schrödinger equation”, Helv. Phys. Acta 45, 802 (1972).
  29. C. R. Hagen, “Scale and conformal transformations in galilean-covariant field theory”, Phys. Rev.  D5, 377 (1972).
  30. J. M. Levy-Leblond, “Nonrelativistic particles and wave equations,” Commun. Math. Phys. 6, 286 (1967)
  31. J. Gomis, M. Novell, “A pseudoclassical description for a nonrelativistic spinning particle. 1. The Levy-leblond Equation”, Phys. Rev. D33, 2212 (1986).
  32. C. Duval, P. A. Horvathy and L. Palla, “Spinors in nonrelativistic Chern-Simons electrodynamics,” Ann. of Phys. 249, 265 (1996) [arXiv:hep-th/9510114 [hep-th]].
  33. P. Roman, J. J. Aghassi, R. M. Santilli, and P. L. Huddleston, “Nonrelativistic composite elementary particles and the conformal Galilei group”, Nuovo Cim. 12, 185 (1972).
  34. G. Burdet, and M. Perrin, “Many-body realization of the Schrödinger algebra”, Lett. Nuovo Cim.  4, 651 (1972)
  35. G. Burdet, M. Perrin, and P. Sorba, “About the Non-Relativistic Structure of the Conformal Algebra,” Commun. Math. Phys. 34, 85 (1973).
  36. U. Niederer, “The maximal kinematical invariance groups of Schrödinger equations with arbitrary potentials”, Helv. Phys. Acta. 47, 167 (1974).
  37. V. de Alfaro, S. Fubini and G. Furlan, “Conformal Invariance in Quantum Mechanics,” Nuovo Cim. A34, 569 (1976)
  38. C.P. Boyer, R.T. Sharp, P. Winternitz, “Symmetry-breaking interaction for the time-dependent Schrödinger equation”, J. Math. Phys. 17, 1439 (1976).
  39. A.G. Nikitin, R.O. Popovych, “Group classification of non-linear Schrödinger equations”, Ukr. Math. J. 53, 1255 (2001) [arxiv:math-ph/0301009].
  40. S. Dhasmana, A. Sen and Z. K. Silagadze, “Equivalence of a harmonic oscillator to a free particle and Eisenhart lift,” Ann. of Phys. 434, 168623 (2021), [arXiv:2106.09523 [quant-ph]].
  41. A. Bihlo, R.O. Popovych, “Group classification of linear evolution equations”, J. Math. Anal. Appl. 448, 982 (2017) [arxiv:1605.09251].
  42. R. Cherniha, J.R. King, “Lie symmetries of nonlinear multidimensional reaction-diffusion systems: I”, J. Phys. A: Math. Gen. 33, 267 (2000); R. Cherniha, J.R. King, “Lie symmetries of nonlinear multidimensional reaction-diffusion systems: II”, J. Phys. A: Math. Gen. 36, 405 (20003).
  43. R. Jackiw, “Dynamical Symmetry of the Magnetic Monopole,” Ann. of Phys. 129, 183 (1980)
  44. R. Jackiw, “Dynamical Symmetry of the Magnetic Vortex,” Ann. of Phys. 201, 83 (1990).
  45. C. Duval, “Quelques procédures géométriques en dynamique des particules,” Doctoral Thesis, Marseille (1982).
  46. R. Jackiw and S. Y. Pi, “Classical and quantal nonrelativistic Chern-Simons theory,” Phys. Rev. D42, 3500 (1990) [erratum: Phys. Rev. D48 3929 (1993)].
  47. C. Duval, P. A. Horvathy and L. Palla, “Conformal symmetry of the coupled Chern-Simons and gauged nonlinear Schrödinger equations,” Phys. Lett. B325, 39 (1994). [arXiv:hep-th/9401065 [hep-th]].
  48. R. Jackiw, “A Particle field theorist’s lectures on supersymmetric, non-abelian fluid mechanics and d-branes,” Lectures CRM Montréal (2000), [arXiv:physics/0010042 [physics]].
  49. M. Hassaine and P. A. Horvathy, “Symmetries of fluid dynamics with polytropic exponent”, Phys. Lett. A279, 215 (2001) [arXiv:hep-th/0009092 [hep-th]].
  50. P. A. Horvathy and P. M. Zhang, “Non-relativistic conformal symmetries in fluid mechanics”, Eur. Phys. J. C65 (2010), 607-614 [arXiv:0906.3594 [physics.flu-dyn]].
  51. M. Henkel “Schrödinger invariance and strongly anisotropic critical systems,” J. Stat. Phys. 75, 1023 (1994) [arXiv:hep-th/9310081].
  52. K. Balasubramanian, J. McGreevy, “Gravity Duals for Nonrelativistic Conformal Field Theories”, Phys. Rev. Lett. 101, 061601 (2008), [arXiv:0804.4053].
  53. D.T. Son, “Toward an AdS/cold atoms correspondence: A geometric realization of the Schrödinger symmetry”, Phys. Rev. D78, 046003 (2008), [arXiv:0804.3972].
  54. D. Minic, M. Pleimling, “Correspondence between nonrelativistic anti-de Sitter space and conformal field theory, and aging-gravity duality”, Phys. Rev.E78, 061108 (2008), [arXiv:0807.3665]; N. Gray, D. Minic, M. Pleimling, “On non-equilibrium physics and string theory ”, Int. J. Mod. Phys. A28, 1330009 (2013), [arXiv:1301.6368].
  55. C.A. Fuertes, S. Moroz, “Correlation functions in the nonrelativistic AdS/CFT correspondence”, Phys. Rev.D79, 106004 (2009), [arXiv:0903.1844].
  56. R.G. Leigh, N.N. Hoang, “Real-time correlators and non-relativistic holography”, J. High Energy Phys. 0911:010,2009 [arXiv:0904.4270]; R.G. Leigh, N.N. Hoang, “Fermions and the Sch/nrCFT Correspondence”, J. High Energy Phys. 1003:027,2010, [arxiv:0909.1883].
  57. S. Moroz, “Nonrelativistic scale anomaly, and composite operators with complex scaling dimensions”, Ann. of Phys. 326, 1368 (2011); [arXiv:1007.4635].
  58. A.O. Barut “Conformal Group →→\to→ Schrödinger Group →→\to→ Dynamical Group — The Maximal Kinematical Group of the Massive Schrödinger Particle,” Helv. Phys. Acta 46, 496 (1973); U. Niederer, “The connections between the Schrödinger group and the conformal group,” Helv. Phys. Acta 47, 119 (1974).
  59. E. Noether, “Invariante Variationsprobleme [Invariants of variational problems],”, Nachr. Ges. Wiss. Göttingen, Math.-Phys., 1918b, p. 235-257, Gött. Nachr.1918:235-257,1918; Transp.Theory Statist. Phys.1:186-207,1971 [arXiv:physics/0503066 [physics.hist-ph]]
  60. C. Duval, G. W. Gibbons, P. A. Horvathy and P. M. Zhang, “Carroll Newton and Galilei: two dual non-Einsteinian concepts of time,” Class. Quant. Grav. 31 (2014), 085016 [arXiv:1402.0657 [gr-qc]].
  61. J. M. Lévy-Leblond, “Une nouvelle limite non-relativiste du group de Poincaré”, Ann. Inst. H. Poincaré 3, 1 (1965).
  62. R. Casalbuoni, D. Dominici and J. Gomis, “Two interacting conformal Carroll particles,” [arXiv:2306.02614 [hep-th]]; P. M. Zhang, H. X. Zeng and P. A. Horvathy, “MultiCarroll dynamics,” [arXiv:2306.07002 [gr-qc]].
  63. L. Marsot, P. M. Zhang, M. Chernodub and P. A. Horvathy, “Hall effects in Carroll dynamics,” Phys. Rep. 1028, 1 (2023) [arXiv:2212.02360 [hep-th]].
  64. J. Kepler, “Astronomia Nova”, [New Astronomy] (1609) chap.59. See https://en.wikipedia.org/wiki/Astronomia−{}_{-}start_FLOATSUBSCRIPT - end_FLOATSUBSCRIPTnova # .
  65. C. Duval, G. W. Gibbons and P. Horvathy, “Celestial mechanics, conformal structures and gravitational waves,” Phys. Rev. D43, 3907 (1991) [arXiv:hep-th/0512188].
  66. P. A. M. Dirac, “A new basis for cosmology,” Proc. Roy. Soc. A165, 199 (1938).
  67. U. Niederer, “The maximal kinematical invariance group of the harmonic oscillator”, Helv. Phys. Acta. 46, 192 (1973).
  68. U. Niederer, “Schrödinger-invariant generalized heat equations”, Helv. Phys. Acta 51, 220 (1978).
  69. E.V. Ivashkevich, “Symmetries of the stochastic Burgers equation”, J. Phys. A30, L525 (1997) [arXiv:hep-th/9610221].
  70. P. Havas, J. Plebanski “Conformal extensions of the Galilei group and their relation to the Schrödinger group,” J. Math. Phys. 19, 482 (1978).
  71. J. Negro, M.A. del Olmo and A. Rodríguez-Marco, “Nonrelativistic conformal groups” I & II, J. Math. Phys. 38, 3786 (1997); 38, 3810 (1997).
  72. M. Henkel, S. Stoimenov, “Infinite-dimensional meta-conformal Lie algebras in one and two spatial dimensions”, J. Stat. Mech. 084009 (2019) [arxiv:1810.09855].
  73. S. Stoimenov, M. Henkel, “Meta-Schrödinger-invariance”, Nucl. Phys. B985, 116020 (2022) [arxiv:2112.14143].
  74. M. W. Brinkmann, “On Riemann spaces conformal to Euclidean spaces”, Proc. Natl. Acad. Sci. U.S. 9, 1 (1923); ‘Èinstein spaces which are mapped conformally on each other”, Math. Ann. 94, 119 (1925).
  75. C. Duval, G. Burdet, H.P. Künzle, and M. Perrin; “Bargmannn Structures and Newton-Cartan Theory,” Phys. Rev. D31, 1841 (1985).
  76. J. Gomis, J.M. Pons, “Poincare Transformations and Galilei Transformations.” Phys. Lett. A66 463 (1978); J. Gomis, A. Poch, J. M. Pons, “Poincare wave equations as Fourier transforms of Galilei wave equations.” J. Math. Phys. 21 2682 (1980).
  77. H. P. Künzle, “Galilei and Lorentz structures on space-time : Comparison of the corresponding geometry and physics”, Ann. Inst. Henri Poincaré 17A, 337 (1972).
  78. C. Duval, G. W. Gibbons, P. A. Horvathy and P. M. Zhang, “Carroll versus Newton and Galilei: two dual non-Einsteinian concepts of time,” Class. Quant. Grav. 31, 085016 (2014) [arXiv:1402.0657 [gr-qc]].
  79. M. Elbistan, N. Dimakis, K. Andrzejewski, P. A. Horvathy, P. Kosínski and P. M. Zhang, “Conformal symmetries and integrals of the motion in pp waves with external electromagnetic fields,” Ann. of Phys. 418, 168180 (2020) [arXiv:2003.07649 [gr-qc]].
  80. H. A. Kastrup, “Gauge properties of the Galilei space,” Nucl. Phys. B7, 545 (1968);
  81. M. Henkel, “Local Scale Invariance and Strongly Anisotropic Equilibrium Critical Systems,” Phys. Rev. Lett. 78, 1940-1943 (1997) [arXiv:cond-mat/9610174].
  82. M. Henkel and J. Unterberger, “Schrödinger invariance and space-time symmetries,” Nucl. Phys. B660, 407-435 (2003) [arXiv:hep-th/0302187].
  83. V. Bargmannn, “On unitary ray representations of continuous groups,” Ann. of Math. 59, 1 (1954)
  84. J.-M. Lévy-Leblond, “Galilei group and Galilean invariance,” in E.M. Loebl (ed.) Group Theory and Applications II, Academic Press (New York 1972); p. 222.
  85. R. Cherniha, M. Henkel, “The exotic conformal Galilei algebra and non-linear partial differential equations”, J. Math. Anal. Appl. 369, 120 (2010) [arxiv:0910.4822].
  86. G. W. Gibbons, “Dark Energy and the Schwarzian Derivative,” [arXiv:1403.5431 [hep-th]].
  87. P. Zhang, Q. Zhao and P. A. Horvathy, “Gravitational waves and conformal time transformations,” Ann. of Phys. 440, 168833 (2022) [arXiv:2112.09589 [gr-qc]].
  88. J-M Souriau, “Sur le mouvement des particules à spin en relativité générale,” C. R. Acad. Sci. Paris Sér. A 271, 751-753 (1970); “Sur le mouvement des particules dans le champ électromagnétique,”; “Modèle de particule à spin dans le champ électromagnétique et gravitationnel,” Ann. Inst. H. Poincaré Sect. A (N.S.) 20, 315-364 (1974); C Duval, H-H Fliche, and J-M Souriau, “Un modèle de particule à spin dans le champ gravitationnel et électromagnétique,” C. R. Acad. Sci. Paris Sér. A274, 1082-1084 (1972)
  89. E. Inönü, and E. P. Wigner, “Representations of the Galilei group,” Il Nuovo Cimento 9, 705 (1952).
  90. G. Gibbons, “Constancy of Total Mass in Classical and Quantum Mechanics”, unpublished notes.
  91. P. M. Zhang, M. Cariglia, M. Elbistan and P. A. Horvathy, “Scaling and conformal symmetries for plane gravitational waves,” J. Math. Phys. 61, 022502 (2020) [arXiv:1905.08661 [gr-qc]].
  92. J-M. Lévy-Leblond, “Galilei Group and Nonrelativistic Quantum Mechanics,” J. Math. Phys 4, 776 (1963).
  93. N. Aizawa, Z. Kuznetsova, F. Toppan, “ℓℓ\ellroman_ℓ-oscillators from second-order invariant PDEs of the centrally extended conformal Galilei algebras”, J. Math. Phys. 56, 031701 (2015), [arXiv:1501.00121].
  94. N. Aizawa, Z. Kuznetsova, F. Toppan, “Invariant partial differential equations with two-dimensional exotic centrally extended conformal Galilei symmetry”, J. Math. Phys. 57, 041701 (2016), [arXiv:1512.02290].
  95. N. Aizawa, Z. Kuznetsova, F. Toppan, “Invariant partial differential equations of conformal Galilei algebra as deformations: cryptohermiticity and contractions”, Prog. Theor. Exp. Phys. 083A01 (2016) [arXiv:1506.08488].
  96. N. Aizawa, T. Kato, “Centrally Extended Conformal Galilei Algebras and Invariant Nonlinear PDEs”, Symmetry 7, 1989 (2015), [arXiv:1506.04377].
  97. I. Masterov, “Towards ℓℓ\ellroman_ℓ-conformal Galilei algebra via contraction of the conformal group”, [arXiv:2309.01588].
  98. A. Galajinsky, and I. Masterov, “Dynamical realizations of ℓℓ\ellroman_ℓ-conformal Newton-Hooke group,” Phys. Lett. B723, 190 (2013) [arXiv:1303.3419 [hep-th]].
  99. A. Galajinky, I. Masterov, “On dynamical realizations of ℓℓ\ellroman_ℓ-conformal Galilei and Newton-Hooke algebras”, Nucl. Phys. B896, 244 (2015) [arXiv:1503.08633].
  100. K. Andrzejewski, A. Galajinsky, J. Gonera, I. Masterov, “Conformal Newton-Hooke symmetry of Pais-Uhlenbeck oscillator”, Nucl. Phys. B885, 150 (2014).
  101. S. Krivonos, O. Lechtenfeld, A. Sorin “Minimal realization of ℓℓ\ellroman_ℓ-conformal Galilei algebra, Pais-Uhlenbeck oscillators and their deformation”, J. High Energy Phys. 10 (2016) 078, [arXiv:1607.03756]; S. Krivonos, O. Lechtenfeld, A. Sorin, “Hidden symmetries of deformed oscillators”, Nucl. Phys. B924, 33 (2017), [arXiv:1612.07832].
  102. T. Snegirev, “Hamiltonian formulation for perfect fluid equations with the ℓℓ\ellroman_ℓ-conformal Galilei symmetry”, [arXiv:2302.01565].
  103. M. Pleimling, M. Henkel, “Anisotropic scaling and generalized conformal invariance at Lifshitz points”, Phys. Rev. Lett. 87, 125702 (2001) [arxiv:hep-th/0103194].
  104. M.A. Shpot, H.W. Diehl, “Two-loop renormalization-group analysis of critical behaviour at m𝑚mitalic_m-axial Lifshitz points”, Nucl. Phys. B612, 340 (2001) [arXiv:cond-mat/0106105].
  105. S. Rutkevich, H.W. Diehl, M.A. Shpot, “On conjectured local generalizations of anisotropic scale invariance and their implications”, Nucl. Phys. B843, 255 (2011) [arXiv:1005.1334]; err. Nucl. Phys B853,210 (2011).
  106. J. Krug, P. Meakin, “Kinetic roughening of laplacian fronts”, Phys. Rev. Lett. 66, 703 (1991).
  107. J. Krug, “Statistical physics of growth processes”, in A. McKane, M. Droz, J. Vannimenus, D. Wolf (eds) Scale invariance, interfaces and non-equilibrium dynamics NATO ASI Series B344, Plenum Press (London 1994), p. 1.
  108. M. Henkel, “Non-local meta-conformal invariance in diffusion-limited erosion”, J. Phys. A49, 49LT02 (2016) [arxiv:1606.06207].
  109. M. Henkel, “Non-local meta-conformal invariance, diffusion-limited erosion and the XXZ chain”, Symmetry 9, 2 (2017) [arxiv:1611.02975].
  110. M. Henkel, S. Stoimenov, “Dynamical symmetries in the non-equilibrium dynamics of the directed spherical model”, Nucl. Phys. B997, 116379 (2023) [arXiv:2305.18155].
  111. D. Giulini, “On Galilei invariance in quantum mechanics and the Bargmannn superselection rule,” Ann. of Phys. 249, 222 (1996) [arXiv:quant-ph/9508002].
  112. M. Henkel, S. Stoimenov “Meta-conformal invariance and the boundedness of two-point correlation functions”, J. Phys. A Math. Theor. 49, 47LT01 (2016) [arxiv:1607.00685].
  113. M. Henkel, M,D. Kuczynski, S. Stoimenov, “Boundedness of meta-conformal two-point functions in one and two spatial dimensions”, J. Phys. A Math. Theor. 53, 475001 (2020) [arxiv:2006.04537].
  114. C. de Dominicis, “Techniques de renormalisation de la théorie de champs et dynamique des phénomènes critiques”, J. Physique (Colloque) 37, C1-247 (1976).
  115. J. Lukierski, P.C. Stichel and W.J. Zakrzewski, “Acceleration-extended galilean symmetries with central charges and their dynamical realizations,” Phys. Lett. B650, 203 (2007) [arXiv:0511259].
  116. A. Bagchi, R. Gopakumar, I. Mandal, A. Miwa, “CGA in 2D”, JHEP 1008:004 (2010), [arXiv:0912.1090].
  117. A. Bagchi, J. Chakrabortty, A. Mehra, “Galilean field theories and conformal structure”, J. High Energy Phys. 2018, 144 (2018), [arXiv:1712.05631].
  118. C. Godrèche, J.-M. Luck, “Nonequilibrium critical dynamics of ferromagnetic spin systems”, J. Phys. Cond. Matter 14, 1589 (2002), [arXiv:cond-mat/0109212].
  119. M. Henkel, “From dynamical scaling to local scale-invariance: a tutorial”, Eur. Phys. J. Spec. Topic 226, 605 (2017) [arxiv:1610.06122].
  120. A. Röthlein, F. Baumann, M. Pleimling, “Symmetry-based determination of space-time functions in nonequilibrium growth processes”, Phys. Rev. E74, 061604 (2006) [arXiv:cond-mat/0609707]; erratum E76, 019901(E) (2007).
  121. A.J. Bray, “Theory of Phase Ordering Kinetics”, Adv. Phys. 43 357 (1994), [arXiv:cond-mat/9501089].
  122. M. Henkel, T. Enss, M. Pleimling, “On the identification of quasiprimary operators in local scale-invariance”, J. Phys. A39, L589 (2006), [arxiv:cond-mat/0605211].
  123. M. Henkel, M. Pleimling, C. Godrèche, J.-M. Luck, “Ageing, phase ordering and conformal invariance”, Phys. Rev. Lett. 87, 265701 (2001) [arxiv:hep-th/0107122].
  124. V. Gurarie, “Logarithmic operators in conformal field theory,” Nucl. Phys. B410, 535 (1993) [arxiv:hep-th/9303160].
  125. M.R. Rahimi Tabar, A. Aghamohammadi, M. Khorrami, “The Logarithmic Conformal Field Theories”, Nucl. Phys. B497, 555 (1997), [arxiv:hep-th/9610168].
  126. M. Henkel, “On logarithmic extensions of local scale-invariance”, Nucl. Phys. B869, 282 (2013) [arXiv:1009.4139].
  127. M. Henkel, S. Rouhani, “Logarithmic correlators or responses in non-relativistic analogues of conformal invariance”, J. Phys. A46, 494004 (2013) [arXiv:1302.7136].
  128. M. Henkel, A. Hosseiny, S. Rouhani, “Logartihmic exotic conformal galilean algebras”, Nucl. Phys. B879, 292 (2014) [arXiv:1311.3457].
  129. A. Hosseiny, A. Naseh, “On holographic realization of logarithmic Galilean conformal algebra”, J. Math. Phys. 52 092501 (2011) [arXiv:1101.2126].
  130. M.R. Setare, V. Kamali, “Galilean Conformal Algebra in Semi-Infinite Space”, Int. J. Mod. Phys. A27, 1250044 (2011), [arXiv:1101.2339].
  131. T. Enss, M. Henkel, A. Picone, U. Schollwöck, “Ageing phenomena without detailed balance: the contact process”, J. Phys. A37, 10479 (2004) [arxiv:cond-mat/0410147].
  132. M. Henkel, J.D. Noh, M. Pleimling, “Phenomenology of aging in the Kardar-Parisi-Zhang equation”, Phys. Rev. E85, 030102(R) (2012) [arXiv:1109.5022].
  133. J. Kelling, G. Ódor, S. Gemming, “Local scale-invariance of the 2+1212+12 + 1-dimensional Kardar-Parisi-Zhang model”, J. Phys. A50, 12LT01 (2017) [arXiv:1609.05795].
  134. F. Sastre, private communication.
  135. S. El Showk, M.F. Paulos, D. Poland, S. Rychkov, D. Simmons-Duffin, A. Vichi, “Solving the 3D Ising Model with the Conformal Bootstrap”, Phys. Rev. D86, 025022 (2012), [arXiv:1203.6064]; S. El Showk, M.F. Paulos, D. Poland, S. Rychkov, D. Simmons-Duffin, A. Vichi, “Solving the 3D Ising Model with the Conformal Bootstrap II. c𝑐citalic_c-Minimization and Precise Critical Exponents”, J. Stat. Phys. 157, 869 (2014), [arXiv:1403.4545].
  136. S. Rychkov, “3⁢D3𝐷3D3 italic_D Ising Model: a view from the Conformal Bootstrap Island,”, Comptes Rendus Physique 21, 185 (2020), [arXiv:2007.14315].
  137. S. Rychkov, N. Su, “New Developments in the Numerical Conformal Bootstrap”, [arXiv:2311.15844].
  138. A. Bagchi, M. Gary, Zodinmawia, “Bondi-Metzner-Sachs bootstrap” Phys. Rev. 96, 025007 (2017), [arXiv:1612.01730]; A. Bagchi, M. Gary, Zodinmawia, “The nuts and bolts of the BMS Bootstrap”, Class. Quantum Grav. 34, 17400 (2017), [arXiv:1705.05890].
  139. B. Chen, P.-X. Hao, R. Liu, Z.-F. Yu, “On Galilean conformal bootstrap”, J. High Energy Phys. 2021, 112 (2021), [arXiv:2011.11092].
  140. A. Bagchi, “Correspondence between Asymptotically Flat Spacetimes and Nonrelativistic Conformal Field Theories,” Phys. Rev. Lett. 105, 171601 (2010), [arXiv:1006.3354 [hep-th]].
  141. C. Duval, G. W. Gibbons and P. A. Horvathy, “Conformal Carroll groups and BMS symmetry,” Class. Quant. Grav. 31, 092001 (2014), [arXiv:1402.5894 [gr-qc]].
  142. J.-M. Lévy-Leblond, “Nonrelativistic Particles and Wave Equations”, Comm. Math. Phys. 6, 286 (1967).
  143. R. Puzalowski, “Galilean supersymmetry,” Acta Phys. Austriaca 50, 45 (1978). Print-78-0349 (KARLSRUHE).
  144. E. D’Hoker and L. Vinet, “Dynamical Supersymmetry of the Magnetic Monopole and the 1/r21superscript𝑟21/r^{2}1 / italic_r start_POSTSUPERSCRIPT 2 end_POSTSUPERSCRIPT Potential,” Commun. Math. Phys. 97, 391 (1985).
  145. J. Beckers, D. Dehin and V. Hussin, “Symmetries and Supersymmetries of the Quantum Harmonic Oscillator,” J. Phys. A Math. Gen. 20, 1137 (1987).
  146. J. P. Gauntlett, J. Gomis and P. K. Townsend, “Supersymmetry and the physical phase space formulation of spinning particles,” Phys. Lett. B248, 288 (1990).
  147. P. A. Horvathy, “Non-Relativistic Conformal and Supersymmetries,” Int. J. Mod. Phys. A3, 339 (1993), [arXiv:0807.0513 [hep-th]].
  148. M. Leblanc, G. Lozano and H. Min, “Extended superconformal Galilean symmetry in Chern-Simons matter systems,” Ann. of Phys. 219, 328(1992), [arXiv:hep-th/9206039 [hep-th]].
  149. C. Duval and P. A. Horvathy, “On Schrödinger superalgebras,” J. Math. Phys. 35 (1994), 2516 (1994), [arXiv:hep-th/0508079 [hep-th]].
  150. M. Henkel, J. Unterberger, “Supersymmetric extensions of Schrödinger-invariance”, Nucl. Phys. B746, 155 (2006), [arxiv:math-ph/0512024].
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