Generalized black holes in three-dimensional spacetime

Abstract: Three-dimensional spacetime with a negative cosmological constant has proven to be a remarkably fertile ground for the study of gravity and higher spin fields. The theory is topological and, since there are no propagating field degrees of freedom, the asymptotic symmetries become all the more crucial. For pure (2+1) gravity they consist of two copies of the Virasoro algebra. There exists a black hole which may be endowed with all the corresponding charges. The pure (2+1) gravity theory may be reformulated in t… Show more

“…On the one hand, our work fits within a wider program of improving the grasp over the Hamiltonian description of bosonic higher-spin theories [28][29][30]. On the other hand, presenting higher-spin charges in Hamiltonian form may help testing the expected thermodynamical properties of the proposed black hole solutions of Vasiliev's equations [31,32], in analogy with what happened for higher-spin black holes in three space-time dimensions [33][34][35][36]. In that case, the distinction between dynamical variables and Lagrange multipliers has been indeed instrumental in introducing the chemical potentials associated to the higherspin charges carried by generalised black holes [36].…”

“…On the other hand, presenting higher-spin charges in Hamiltonian form may help testing the expected thermodynamical properties of the proposed black hole solutions of Vasiliev's equations [31,32], in analogy with what happened for higher-spin black holes in three space-time dimensions [33][34][35][36]. In that case, the distinction between dynamical variables and Lagrange multipliers has been indeed instrumental in introducing the chemical potentials associated to the higherspin charges carried by generalised black holes [36]. The exact solutions of [31,32] are also expected to be endowed with higher-spin charges [16], 1 but the study of their thermodynamics is still in its infancy (although entropy and thermal equilibrium should be the most striking signatures of a "generalised" black hole).…”

“…The covariant boundary conditions (2.22) would also fix the falloff of the Lagrange multipliers. The resulting conditions, however, would correspond to a particular choice of gauge, while -as noticed in three space-time dimensions [36,52] -the freedom in the choice of the Lagrange multipliers is instrumental in fitting some physically relevant solutions within the boundary conditions (see also [53]). We postpone to future work a detailed analysis of this issue, especially because this freedom does not affect charges.…”

“…In three space-time dimensions, the rewriting (2.43) exhibits the chiral splitting of charges that one obtains in the Chern-Simons formulation with a suitable choice of the boundary value of the Lagrange multipliers [19,20,36]. Introducing the light-cone coordinates x ± = t ± φ, one obtains…”

Higher-spin charges in Hamiltonian form. I. Bose fields

“…On the one hand, our work fits within a wider program of improving the grasp over the Hamiltonian description of bosonic higher-spin theories [28][29][30]. On the other hand, presenting higher-spin charges in Hamiltonian form may help testing the expected thermodynamical properties of the proposed black hole solutions of Vasiliev's equations [31,32], in analogy with what happened for higher-spin black holes in three space-time dimensions [33][34][35][36]. In that case, the distinction between dynamical variables and Lagrange multipliers has been indeed instrumental in introducing the chemical potentials associated to the higherspin charges carried by generalised black holes [36].…”

“…On the other hand, presenting higher-spin charges in Hamiltonian form may help testing the expected thermodynamical properties of the proposed black hole solutions of Vasiliev's equations [31,32], in analogy with what happened for higher-spin black holes in three space-time dimensions [33][34][35][36]. In that case, the distinction between dynamical variables and Lagrange multipliers has been indeed instrumental in introducing the chemical potentials associated to the higherspin charges carried by generalised black holes [36]. The exact solutions of [31,32] are also expected to be endowed with higher-spin charges [16], 1 but the study of their thermodynamics is still in its infancy (although entropy and thermal equilibrium should be the most striking signatures of a "generalised" black hole).…”

“…The covariant boundary conditions (2.22) would also fix the falloff of the Lagrange multipliers. The resulting conditions, however, would correspond to a particular choice of gauge, while -as noticed in three space-time dimensions [36,52] -the freedom in the choice of the Lagrange multipliers is instrumental in fitting some physically relevant solutions within the boundary conditions (see also [53]). We postpone to future work a detailed analysis of this issue, especially because this freedom does not affect charges.…”

“…In three space-time dimensions, the rewriting (2.43) exhibits the chiral splitting of charges that one obtains in the Chern-Simons formulation with a suitable choice of the boundary value of the Lagrange multipliers [19,20,36]. Introducing the light-cone coordinates x ± = t ± φ, one obtains…”

Higher-spin charges in Hamiltonian form. I. Bose fields

“…and to situations where Bekenstein-Hawking fails, such as higher spin [27,28] black holes [29,30], where even for the simplest case of spin-3 black holes the entropy looks fairly complicated [31] (L ± 0 and c are the same as in the spin-2 case; W ± 0 denotes the spin-3 zero mode charges with suitable normalization; for W ± 0 = 0 the Cardy formula (8) is recovered)…”

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