BMS3 (Carrollian) field theories from a bound in the coupling of current-current deformations of CFT2

Pulastya Parekh; David Tempo; Ricardo Troncoso

doi:10.1007/JHEP09(2023)083

BMS₃ (Carrollian) field theories from a bound in the coupling of current-current deformations of CFT₂

Pulastya Parekh, David Tempo, Ricardo Troncoso^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

Two types of Carrollian field theories are shown to emerge from finite current-current deformations of toroidal CFT₂’s when the deformation coupling is precisely fixed, up to a sign. In both cases the energy and momentum densities fulfill the BMS₃ algebra. Applying these results to the bosonic string, one finds that the electric-like deformation (positive coupling) reduces to the standard tensionless string. The magnetic-like deformation (negative coupling) yields to a new theory, still being relativistic, devoid of tension and endowed with an “inner Carrollian structure”. Classical solutions describe a sort of “self-interacting null particle” moving along generic null curves of the original background metric, not necessarily geodesics. This magnetic-like theory is also shown to be recovered from inequivalent limits in the tension of the bosonic string. Electric- and magnetic-like deformations of toroidal CFT₂’s can be seen to correspond to limiting cases of continuous exactly marginal (trivial) deformations spanned by an SO(1,1) automorphism of the current algebra. Thus, the absolute value of the current-current deformation coupling is shown to be bounded. When the bound saturates, the deformation ceases to be exactly marginal, but still retains the full conformal symmetry in two alternative ultrarelativistic regimes.

Original language	English
Article number	83
Journal	Journal of High Energy Physics
Volume	2023
Issue number	9
DOIs	https://doi.org/10.1007/JHEP09(2023)083
State	Published - 2023

Bibliographical note

Funding Information:
We thank Arjun Bagchi, Aritra Banerjee, Glenn Barnich, Geoffrey Compère, Stéphane Detournay, José Edelstein, Oscar Fuentealba, Gaston Giribet, Andrés Gomberoff, Hernán González, Marc Henneaux, Diego Hidalgo, Javier Matulich, Alfredo Pérez, Miguel Pino, Pablo Rodríguez and Patricio Salgado-Rebolledo for useful comments and discussions. RT thanks the organizers of the Solvay Workshop on “Progress on gravitational physics: 45 years of Belgian-Chilean collaboration”, during April 2023 in Brussels, for the opportunity of presenting this work in a wonderful atmosphere. DT and RT also thank the Physique Théorique et Mathématique group of the Université Libre de Bruxelles and the International Solvay Institutes for the kind hospitality. RT thanks the support of Vicerrectoría de Investigación y Doctorados de la Universidad San Sebastián, Chile — fund ‘USS-FIN-23-PASI-10’. This research has been partially supported by ANID FONDECYT grants N° 1211226, 1220910, 1221624 and 3210558.

Funding Information:
We thank Arjun Bagchi, Aritra Banerjee, Glenn Barnich, Geoffrey Compère, Stéphane Detournay, José Edelstein, Oscar Fuentealba, Gaston Giribet, Andrés Gomberoff, Hernán González, Marc Henneaux, Diego Hidalgo, Javier Matulich, Alfredo Pérez, Miguel Pino, Pablo Rodríguez and Patricio Salgado-Rebolledo for useful comments and discussions. RT thanks the organizers of the Solvay Workshop on “Progress on gravitational physics: 45 years of Belgian-Chilean collaboration”, during April 2023 in Brussels, for the opportunity of presenting this work in a wonderful atmosphere. DT and RT also thank the Physique Théorique et Mathématique group of the Université Libre de Bruxelles and the International Solvay Institutes for the kind hospitality. RT thanks the support of Vicerrectoría de Investigación y Doctorados de la Universidad San Sebastián, Chile — fund ‘USS-FIN-23-PASI-10’. This research has been partially supported by ANID FONDECYT grants N° 1211226, 1220910, 1221624 and 3210558.

Publisher Copyright:
© 2023, The Author(s).

ASJC Scopus subject areas

Nuclear and High Energy Physics

Access to Document

10.1007/JHEP09(2023)083

Cite this

@article{8afb1bccc745437e88ba61eeb9b0ad50,

title = "BMS3 (Carrollian) field theories from a bound in the coupling of current-current deformations of CFT2",

abstract = "Two types of Carrollian field theories are shown to emerge from finite current-current deformations of toroidal CFT2{\textquoteright}s when the deformation coupling is precisely fixed, up to a sign. In both cases the energy and momentum densities fulfill the BMS3 algebra. Applying these results to the bosonic string, one finds that the electric-like deformation (positive coupling) reduces to the standard tensionless string. The magnetic-like deformation (negative coupling) yields to a new theory, still being relativistic, devoid of tension and endowed with an “inner Carrollian structure”. Classical solutions describe a sort of “self-interacting null particle” moving along generic null curves of the original background metric, not necessarily geodesics. This magnetic-like theory is also shown to be recovered from inequivalent limits in the tension of the bosonic string. Electric- and magnetic-like deformations of toroidal CFT2{\textquoteright}s can be seen to correspond to limiting cases of continuous exactly marginal (trivial) deformations spanned by an SO(1,1) automorphism of the current algebra. Thus, the absolute value of the current-current deformation coupling is shown to be bounded. When the bound saturates, the deformation ceases to be exactly marginal, but still retains the full conformal symmetry in two alternative ultrarelativistic regimes.",

keywords = "Conformal and W Symmetry, Space-Time Symmetries",

author = "Pulastya Parekh and David Tempo and Ricardo Troncoso",

note = "Funding Information: We thank Arjun Bagchi, Aritra Banerjee, Glenn Barnich, Geoffrey Comp{\`e}re, St{\'e}phane Detournay, Jos{\'e} Edelstein, Oscar Fuentealba, Gaston Giribet, Andr{\'e}s Gomberoff, Hern{\'a}n Gonz{\'a}lez, Marc Henneaux, Diego Hidalgo, Javier Matulich, Alfredo P{\'e}rez, Miguel Pino, Pablo Rodr{\'i}guez and Patricio Salgado-Rebolledo for useful comments and discussions. RT thanks the organizers of the Solvay Workshop on “Progress on gravitational physics: 45 years of Belgian-Chilean collaboration”, during April 2023 in Brussels, for the opportunity of presenting this work in a wonderful atmosphere. DT and RT also thank the Physique Th{\'e}orique et Math{\'e}matique group of the Universit{\'e} Libre de Bruxelles and the International Solvay Institutes for the kind hospitality. RT thanks the support of Vicerrector{\'i}a de Investigaci{\'o}n y Doctorados de la Universidad San Sebasti{\'a}n, Chile — fund {\textquoteleft}USS-FIN-23-PASI-10{\textquoteright}. This research has been partially supported by ANID FONDECYT grants N° 1211226, 1220910, 1221624 and 3210558. Funding Information: We thank Arjun Bagchi, Aritra Banerjee, Glenn Barnich, Geoffrey Comp{\`e}re, St{\'e}phane Detournay, Jos{\'e} Edelstein, Oscar Fuentealba, Gaston Giribet, Andr{\'e}s Gomberoff, Hern{\'a}n Gonz{\'a}lez, Marc Henneaux, Diego Hidalgo, Javier Matulich, Alfredo P{\'e}rez, Miguel Pino, Pablo Rodr{\'i}guez and Patricio Salgado-Rebolledo for useful comments and discussions. RT thanks the organizers of the Solvay Workshop on “Progress on gravitational physics: 45 years of Belgian-Chilean collaboration”, during April 2023 in Brussels, for the opportunity of presenting this work in a wonderful atmosphere. DT and RT also thank the Physique Th{\'e}orique et Math{\'e}matique group of the Universit{\'e} Libre de Bruxelles and the International Solvay Institutes for the kind hospitality. RT thanks the support of Vicerrector{\'i}a de Investigaci{\'o}n y Doctorados de la Universidad San Sebasti{\'a}n, Chile — fund {\textquoteleft}USS-FIN-23-PASI-10{\textquoteright}. This research has been partially supported by ANID FONDECYT grants N° 1211226, 1220910, 1221624 and 3210558. Publisher Copyright: {\textcopyright} 2023, The Author(s).",

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N1 - Funding Information: We thank Arjun Bagchi, Aritra Banerjee, Glenn Barnich, Geoffrey Compère, Stéphane Detournay, José Edelstein, Oscar Fuentealba, Gaston Giribet, Andrés Gomberoff, Hernán González, Marc Henneaux, Diego Hidalgo, Javier Matulich, Alfredo Pérez, Miguel Pino, Pablo Rodríguez and Patricio Salgado-Rebolledo for useful comments and discussions. RT thanks the organizers of the Solvay Workshop on “Progress on gravitational physics: 45 years of Belgian-Chilean collaboration”, during April 2023 in Brussels, for the opportunity of presenting this work in a wonderful atmosphere. DT and RT also thank the Physique Théorique et Mathématique group of the Université Libre de Bruxelles and the International Solvay Institutes for the kind hospitality. RT thanks the support of Vicerrectoría de Investigación y Doctorados de la Universidad San Sebastián, Chile — fund ‘USS-FIN-23-PASI-10’. This research has been partially supported by ANID FONDECYT grants N° 1211226, 1220910, 1221624 and 3210558. Funding Information: We thank Arjun Bagchi, Aritra Banerjee, Glenn Barnich, Geoffrey Compère, Stéphane Detournay, José Edelstein, Oscar Fuentealba, Gaston Giribet, Andrés Gomberoff, Hernán González, Marc Henneaux, Diego Hidalgo, Javier Matulich, Alfredo Pérez, Miguel Pino, Pablo Rodríguez and Patricio Salgado-Rebolledo for useful comments and discussions. RT thanks the organizers of the Solvay Workshop on “Progress on gravitational physics: 45 years of Belgian-Chilean collaboration”, during April 2023 in Brussels, for the opportunity of presenting this work in a wonderful atmosphere. DT and RT also thank the Physique Théorique et Mathématique group of the Université Libre de Bruxelles and the International Solvay Institutes for the kind hospitality. RT thanks the support of Vicerrectoría de Investigación y Doctorados de la Universidad San Sebastián, Chile — fund ‘USS-FIN-23-PASI-10’. This research has been partially supported by ANID FONDECYT grants N° 1211226, 1220910, 1221624 and 3210558. Publisher Copyright: © 2023, The Author(s).

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N2 - Two types of Carrollian field theories are shown to emerge from finite current-current deformations of toroidal CFT2’s when the deformation coupling is precisely fixed, up to a sign. In both cases the energy and momentum densities fulfill the BMS3 algebra. Applying these results to the bosonic string, one finds that the electric-like deformation (positive coupling) reduces to the standard tensionless string. The magnetic-like deformation (negative coupling) yields to a new theory, still being relativistic, devoid of tension and endowed with an “inner Carrollian structure”. Classical solutions describe a sort of “self-interacting null particle” moving along generic null curves of the original background metric, not necessarily geodesics. This magnetic-like theory is also shown to be recovered from inequivalent limits in the tension of the bosonic string. Electric- and magnetic-like deformations of toroidal CFT2’s can be seen to correspond to limiting cases of continuous exactly marginal (trivial) deformations spanned by an SO(1,1) automorphism of the current algebra. Thus, the absolute value of the current-current deformation coupling is shown to be bounded. When the bound saturates, the deformation ceases to be exactly marginal, but still retains the full conformal symmetry in two alternative ultrarelativistic regimes.

AB - Two types of Carrollian field theories are shown to emerge from finite current-current deformations of toroidal CFT2’s when the deformation coupling is precisely fixed, up to a sign. In both cases the energy and momentum densities fulfill the BMS3 algebra. Applying these results to the bosonic string, one finds that the electric-like deformation (positive coupling) reduces to the standard tensionless string. The magnetic-like deformation (negative coupling) yields to a new theory, still being relativistic, devoid of tension and endowed with an “inner Carrollian structure”. Classical solutions describe a sort of “self-interacting null particle” moving along generic null curves of the original background metric, not necessarily geodesics. This magnetic-like theory is also shown to be recovered from inequivalent limits in the tension of the bosonic string. Electric- and magnetic-like deformations of toroidal CFT2’s can be seen to correspond to limiting cases of continuous exactly marginal (trivial) deformations spanned by an SO(1,1) automorphism of the current algebra. Thus, the absolute value of the current-current deformation coupling is shown to be bounded. When the bound saturates, the deformation ceases to be exactly marginal, but still retains the full conformal symmetry in two alternative ultrarelativistic regimes.

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