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Carroll-Schrödinger Equation

Published 17 Mar 2024 in hep-th | (2403.11212v4)

Abstract: The Poincar\'e symmetry can be contracted in two ways to yield the Galilei symmetry and the Carroll symmetry. The well-known Schr\"odinger equation exhibits the Galilei symmetry and is a fundamental equation in Galilean quantum mechanics. However, the question remains: what is the quantum equation that corresponds to the Carroll symmetry? In this paper, we derive a novel equation in two dimensions, called the Carroll-Schr\"odinger equation'', which describes the quantum dynamics in the Carrollian framework. We also construct the so-calledCarroll-Schr\"odinger algebra'' in two dimensions, which is a conformal extension of the centrally extended Carroll algebra with a dynamical exponent of $z=1/2$. We demonstrate that this algebra is the symmetry algebra of the Carroll-Schr\"odinger field theory. Moreover, we apply the method of canonical quantization to the theory and utilize it to compute the transition amplitude. Finally, we discuss higher dimensions and identify the so-called ``generalized Carroll-Schr\"odinger equation''.

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References (66)
  1. J.-M. Lévy-Leblond, “Une nouvelle limite non-relativiste du groupe de Poincaré”, Annales de l’I.H.P. Physique théorique 3[1] (1965) 1.
  2. 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 (2014) 085016, arXiv:1402.0657 [gr-qc].
  3. C. Duval, G. W. Gibbons and P. A. Horvathy, “Conformal Carroll groups and BMS symmetry”, Class. Quant. Grav. 31 (2014) 092001, arXiv:1402.5894 [gr-qc].
  4. G. Barnich and C. Troessaert, “Symmetries of asymptotically flat 4 dimensional spacetimes at null infinity revisited”, Phys. Rev. Lett. 105 (2010) 111103, arXiv:0909.2617 [gr-qc].
  5. A. Bagchi, “Correspondence between Asymptotically Flat Spacetimes and Nonrelativistic Conformal Field Theories”, Phys. Rev. Lett. 105 (2010) 171601, arXiv:1006.3354 [hep-th].
  6. L. Ciambelli, C. Marteau, A. C. Petkou, P. M. Petropoulos and K. Siampos, “Flat holography and Carrollian fluids”, JHEP 07 (2018) 165, arXiv:1802.06809 [hep-th].
  7. J. Figueroa-O’Farrill, E. Have, S. Prohazka and J. Salzer, “Carrollian and celestial spaces at infinity”, JHEP 09 (2022) 007, arXiv:2112.03319 [hep-th].
  8. Y. Herfray, “Carrollian manifolds and null infinity: a view from Cartan geometry”, Class. Quant. Grav. 39[21] (2022) 215005, arXiv:2112.09048 [gr-qc].
  9. A. Bagchi, S. Banerjee, R. Basu and S. Dutta, “Scattering Amplitudes: Celestial and Carrollian”, Phys. Rev. Lett. 128[24] (2022) 241601, arXiv:2202.08438 [hep-th].
  10. L. Donnay, A. Fiorucci, Y. Herfray and R. Ruzziconi, “Carrollian Perspective on Celestial Holography”, Phys. Rev. Lett. 129[7] (2022) 071602, arXiv:2202.04702 [hep-th].
  11. A. Campoleoni, L. Ciambelli, A. Delfante, C. Marteau, P. M. Petropoulos and R. Ruzziconi, “Holographic Lorentz and Carroll frames”, JHEP 12 (2022) 007, arXiv:2208.07575 [hep-th].
  12. L. Donnay, A. Fiorucci, Y. Herfray and R. Ruzziconi, “Bridging Carrollian and celestial holography”, Phys. Rev. D 107[12] (2023) 126027, arXiv:2212.12553 [hep-th].
  13. A. Bagchi, P. Dhivakar and S. Dutta, “AdS Witten diagrams to Carrollian correlators”, JHEP 04 (2023) 135, arXiv:2303.07388 [hep-th].
  14. A. Saha, “Carrollian approach to 1 + 3D flat holography”, JHEP 06 (2023) 051, arXiv:2304.02696 [hep-th].
  15. J. Salzer, “An embedding space approach to Carrollian CFT correlators for flat space holography”, JHEP 10 (2023) 084, arXiv:2304.08292 [hep-th].
  16. A. Campoleoni, A. Delfante, S. Pekar, P. M. Petropoulos, D. Rivera-Betancour and M. Vilatte, “Flat from anti de Sitter”, JHEP 12 (2023) 078, arXiv:2309.15182 [hep-th].
  17. M. Henneaux, “Geometry of Zero Signature Space-times”, Bull. Soc. Math. Belg. 31 (1979) 47.
  18. G. Dautcourt, “On the ultrarelativistic limit of general relativity”, Acta Phys. Polon. B 29 (1998) 1047, arXiv:gr-qc/9801093.
  19. J. Nzotungicimpaye, “Kinematical versus Dynamical Contractions of the de Sitter Lie algebras”, J. Phys. Comm. 3[10] (2019) 105003, arXiv:1406.0972 [math-ph].
  20. E. Bergshoeff, J. Gomis and L. Parra, “The Symmetries of the Carroll Superparticle”, J. Phys. A 49[18] (2016) 185402, arXiv:1503.06083 [hep-th].
  21. X. Bekaert and K. Morand, “Connections and dynamical trajectories in generalised Newton-Cartan gravity II. An ambient perspective”, J. Math. Phys. 59[7] (2018) 072503, arXiv:1505.03739 [hep-th].
  22. J. Hartong, “Gauging the Carroll Algebra and Ultra-Relativistic Gravity”, JHEP 08 (2015) 069, arXiv:1505.05011 [hep-th].
  23. E. Bergshoeff, J. Gomis, B. Rollier, J. Rosseel and T. ter Veldhuis, “Carroll versus Galilei Gravity”, JHEP 03 (2017) 165, arXiv:1701.06156 [hep-th].
  24. C. Duval, G. W. Gibbons, P. A. Horvathy and P. M. Zhang, “Carroll symmetry of plane gravitational waves”, Class. Quant. Grav. 34[17] (2017) 175003, arXiv:1702.08284 [gr-qc].
  25. J. de Boer, J. Hartong, N. A. Obers, W. Sybesma and S. Vandoren, “Perfect Fluids”, SciPost Phys. 5[1] (2018) 003, arXiv:1710.04708 [hep-th].
  26. L. Ciambelli, C. Marteau, A. C. Petkou, P. M. Petropoulos and K. Siampos, “Covariant Galilean versus Carrollian hydrodynamics from relativistic fluids”, Class. Quant. Grav. 35[16] (2018) 165001, arXiv:1802.05286 [hep-th].
  27. L. Ciambelli and C. Marteau, “Carrollian conservation laws and Ricci-flat gravity”, Class. Quant. Grav. 36[8] (2019) 085004, arXiv:1810.11037 [hep-th].
  28. K. Morand, “Embedding Galilean and Carrollian geometries I. Gravitational waves”, J. Math. Phys. 61[8] (2020) 082502, arXiv:1811.12681 [hep-th].
  29. R. F. Penna, “Near-horizon Carroll symmetry and black hole Love numbers”, arXiv:1812.05643 [hep-th].
  30. L. Donnay and C. Marteau, “Carrollian Physics at the Black Hole Horizon”, Class. Quant. Grav. 36[16] (2019) 165002, arXiv:1903.09654 [hep-th].
  31. E. Bergshoeff, J. M. Izquierdo, T. Ortín and L. Romano, “Lie Algebra Expansions and Actions for Non-Relativistic Gravity”, JHEP 08 (2019) 048, arXiv:1904.08304 [hep-th].
  32. L. Ravera, “AdS Carroll Chern-Simons supergravity in 2 + 1 dimensions and its flat limit”, Phys. Lett. B 795 (2019) 331, arXiv:1905.00766 [hep-th].
  33. L. Ciambelli, R. G. Leigh, C. Marteau and P. M. Petropoulos, “Carroll Structures, Null Geometry and Conformal Isometries”, Phys. Rev. D 100[4] (2019) 046010, arXiv:1905.02221 [hep-th].
  34. A. Ballesteros, G. Gubitosi and F. J. Herranz, “Lorentzian Snyder spacetimes and their Galilei and Carroll limits from projective geometry”, Class. Quant. Grav. 37[19] (2020) 195021, arXiv:1912.12878 [hep-th].
  35. E. Bergshoeff, J. M. Izquierdo and L. Romano, “Carroll versus Galilei from a Brane Perspective”, JHEP 10 (2020) 066, arXiv:2003.03062 [hep-th].
  36. M. Niedermaier, “Nonstandard Action of Diffeomorphisms and Gravity’s Anti-Newtonian Limit”, Symmetry 12[5] (2020) 752.
  37. J. Gomis, D. Hidalgo and P. Salgado-Rebolledo, “Non-relativistic and Carrollian limits of Jackiw-Teitelboim gravity”, JHEP 05 (2021) 162, arXiv:2011.15053 [hep-th].
  38. D. Grumiller, J. Hartong, S. Prohazka and J. Salzer, “Limits of JT gravity”, JHEP 02 (2021) 134, arXiv:2011.13870 [hep-th].
  39. D. Hansen, N. A. Obers, G. Oling and B. T. Søgaard, “Carroll Expansion of General Relativity”, SciPost Phys. 13[3] (2022) 055, arXiv:2112.12684 [hep-th].
  40. J. de Boer, J. Hartong, N. A. Obers, W. Sybesma and S. Vandoren, “Carroll Symmetry, Dark Energy and Inflation”, Front. in Phys. 10 (2022) 810405, arXiv:2110.02319 [hep-th].
  41. M. Henneaux and P. Salgado-Rebolledo, “Carroll contractions of Lorentz-invariant theories”, JHEP 11 (2021) 180, arXiv:2109.06708 [hep-th].
  42. P. Concha, D. Peñafiel, L. Ravera and E. Rodríguez, “Three-dimensional Maxwellian Carroll gravity theory and the cosmological constant”, Phys. Lett. B 823 (2021) 136735, arXiv:2107.05716 [hep-th].
  43. A. Pérez, “Asymptotic symmetries in Carrollian theories of gravity”, JHEP 12 (2021) 173, arXiv:2110.15834 [hep-th].
  44. J. Figueroa-O’Farrill, E. Have, S. Prohazka and J. Salzer, “The gauging procedure and carrollian gravity”, JHEP 09 (2022) 243, arXiv:2206.14178 [hep-th].
  45. A. Campoleoni, M. Henneaux, S. Pekar, A. Pérez and P. Salgado-Rebolledo, “Magnetic Carrollian gravity from the Carroll algebra”, JHEP 09 (2022) 127, arXiv:2207.14167 [hep-th].
  46. S. Baiguera, G. Oling, W. Sybesma and B. T. Søgaard, “Conformal Carroll scalars with boosts”, SciPost Phys. 14[4] (2023) 086, arXiv:2207.03468 [hep-th].
  47. A. Pérez, “Asymptotic symmetries in Carrollian theories of gravity with a negative cosmological constant”, JHEP 09 (2022) 044, arXiv:2202.08768 [hep-th].
  48. O. Fuentealba, M. Henneaux, P. Salgado-Rebolledo and J. Salzer, “Asymptotic structure of Carrollian limits of Einstein-Yang-Mills theory in four spacetime dimensions”, Phys. Rev. D 106[10] (2022) 104047, arXiv:2207.11359 [hep-th].
  49. L. Marsot, P. M. Zhang, M. Chernodub and P. A. Horvathy, “Hall effects in Carroll dynamics”, Phys. Rept. 1028 (2023) 1, arXiv:2212.02360 [hep-th].
  50. E. A. Bergshoeff, J. Gomis and A. Kleinschmidt, “Non-Lorentzian theories with and without constraints”, JHEP 01 (2023) 167, arXiv:2210.14848 [hep-th].
  51. A. Banerjee, S. Dutta and S. Mondal, “Carroll fermions in two dimensions”, Phys. Rev. D 107[12] (2023) 125020, arXiv:2211.11639 [hep-th].
  52. A. Bagchi, A. Banerjee, R. Basu, M. Islam and S. Mondal, “Magic fermions: Carroll and flat bands”, JHEP 03 (2023) 227, arXiv:2211.11640 [hep-th].
  53. A. Bagchi, D. Grumiller and P. Nandi, “Carrollian superconformal theories and super BMS”, JHEP 05 (2022) 044, arXiv:2202.01172 [hep-th].
  54. X. Bekaert, A. Campoleoni and S. Pekar, “Carrollian conformal scalar as flat-space singleton”, Phys. Lett. B 838 (2023) 137734, arXiv:2211.16498 [hep-th].
  55. J. de Boer, J. Hartong, N. A. Obers, W. Sybesma and S. Vandoren, “Carroll stories”, JHEP 09 (2023) 148, arXiv:2307.06827 [hep-th].
  56. F. Ecker, D. Grumiller, J. Hartong, A. Pérez, S. Prohazka and R. Troncoso, “Carroll black holes”, SciPost Phys. 15[6] (2023) 245, arXiv:2308.10947 [hep-th].
  57. K. Koutrolikos and M. Najafizadeh, “Super-Carrollian and Super-Galilean Field Theories”, Phys. Rev. D 108[12] (2023) 125014, arXiv:2309.16786 [hep-th].
  58. O. Kasikci, M. Ozkan, Y. Pang and U. Zorba, “Carrollian Supersymmetry and SYK-like models”, arXiv:2311.00039 [hep-th].
  59. L. Ciambelli and D. Grumiller, “Carroll geodesics”, arXiv:2311.04112 [hep-th].
  60. L. Ciambelli, “Dynamics of Carrollian Scalar Fields”, arXiv:2311.04113 [hep-th].
  61. E. A. Bergshoeff, A. Campoleoni, A. Fontanella, L. Mele and J. Rosseel, “Carroll Fermions”, arXiv:2312.00745 [hep-th].
  62. M. Leblanc, G. Lozano and H. Min, “Extended superconformal Galilean symmetry in Chern-Simons matter systems”, Annals Phys. 219 (1992) 328, arXiv:hep-th/9206039.
  63. R. Jackiw and S.-Y. Pi, “Classical and quantal nonrelativistic Chern-Simons theory”, Phys. Rev. D 42 (1990) 3500, [Erratum: Phys.Rev.D 48, 3929 (1993)].
  64. M. Henkel, “Schrodinger invariance in strongly anisotropic critical systems”, J. Statist. Phys. 75 (1994) 1023, arXiv:hep-th/9310081.
  65. Y. Nishida and D. T. Son, “Nonrelativistic conformal field theories”, Phys. Rev. D 76 (2007) 086004, arXiv:0706.3746 [hep-th].
  66. V. Vysin, “Nonrelativistic Reduction and Interpretation of the Klein-Gordon Equation of Tachyons”, Nuovo Cim. A 40 (1977) 113.
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  1. Mojtaba Najafizadeh 

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