Holographic Second Laws of Black Hole Thermodynamics
From Thermodynamics of Computation
- reference groups
- General Non-equilibrium Statistical Physics
- author-supplied keywords
- keywords
- authors
- Alice Bernamonti
- Federico Galli
- Robert C. Myers
- Jonathan Oppenheim
- title
- Holographic Second Laws of Black Hole Thermodynamics
- type
- journal
- year
- 2018
- pages
- 70
- volume
- 2018
- issue
- 6
- publisher
- Springer Nature
- abstract
- Recently, it has been shown that for out-of-equilibrium systems, there are additional constraints on thermodynamical evolution besides the ordinary second law. These form a new family of second laws of thermodynamics, which are equivalent to the monotonicity of quantum Rényi divergences. In black hole thermodynamics, the usual second law is manifest as the area increase theorem. Hence one may ask if these additional laws imply new restrictions for gravitational dynamics, such as for out-of-equilibrium black holes? Inspired by this question, we study these constraints within the AdS/CFT correspondence. First, we show that the Rényi divergence can be computed via a Euclidean path integral for a certain class of excited CFT states. Applying this construction to the boundary CFT, the Rényi divergence is evaluated as the renormalized action for a particular bulk solution of a minimally coupled gravity-scalar system. Further, within this framework, we show that there exist transitions which are allowed by the traditional second law, but forbidden by the additional thermodynamical constraints. We speculate on the implications of our findings.
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- Citation count
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Identifiers
- doi: https://doi.org/10.1007/JHEP07(2018)111 (Google search)
- issn: 1029-8479
- arxiv: https://arxiv.org/abs/1803.03633
- websites: https://link.springer.com/article/10.1007/JHEP07(2018)111