Horizon thermodynamics of Lovelock black holes David Kubizňák (Perimeter Institute) Black Holes' New Horizons Casa Matemática Oaxaca, BIRS, Oaxaca, Mexico.

Slides:

Advertisements

Similar presentations

F. Debbasch (LERMA-ERGA Université Paris 6) and M. Bustamante, C. Chevalier, Y. Ollivier Statistical Physics and relativistic gravity ( )

Advertisements

Thanks to the organizers for bringing us together!

Rainbow Gravity and the Very Early Universe Yi Ling Center for Gravity and Relativistic Astrophysics Nanchang University, China Nov. 4, Workshop.

{Based on PRD 81 (2010) [ ], joint work with X.-N. Wu}

ASYMPTOTIC STRUCTURE IN HIGHER DIMENSIONS AND ITS CLASSIFICATION KENTARO TANABE (UNIVERSITY OF BARCELONA) based on KT, Kinoshita and Shiromizu PRD

Entropic Gravity SISSA, Statistical Physics JC Friday 28, 2011 E. Verlinde, arXiv: v2 [hep-th]

July 2005 Einstein Conference Paris Thermodynamics of a Schwarzschild black hole observed with finite precision C. Chevalier 1, F. Debbasch 1, M. Bustamante.

Non-Localizability of Electric Coupling and Gravitational Binding of Charged Objects Matthew Corne Eastern Gravity Meeting 11 May 12-13, 2008.

The attractor mechanism, C-functions and aspects of holography in Lovelock gravity Mohamed M. Anber November HET bag-lunch.

Gerard ’t Hooft Spinoza Institute Utrecht University CMI, Chennai, 20 November 2009 arXiv:

Microscopic entropy of the three-dimensional rotating black hole of BHT massive gravity of BHT massive gravity Ricardo Troncoso Ricardo Troncoso In collaboration.

Spin, Charge, and Topology in low dimensions BIRS, Banff, July 29 - August 3, 2006.

Robert Mann D. Kubiznak, N. Altimirano, S. Gunasekaran, B. Dolan, D. Kastor, J. Traschen, Z. Sherkatgnad D.Kubiznak, R.B. Mann JHEP 1207 (2012) 033 S.

On the effects of relaxing On the effects of relaxing the asymptotics of gravity in three dimensions in three dimensions Ricardo Troncoso Centro de Estudios.

Black Hole Thermodynamics with Lambda: Some Consequences  David Kubizňák (Perimeter Institute) Lambda and Quasi-Lambda workshop University of Massachusetts,

几个有趣的黑洞解蔡荣根中国科学院理论物理研究所 (中科大交叉中心，）.

Renormalization group scale-setting in astrophysical systems Silvije Domazet Ru đ er Bošković Institute,Zagreb Theoretical Physics Division th.

Based on Phys.Rev.D84:043515,2011,arXiv: &JCAP01(2012)016 Phys.Rev.D84:043515,2011,arXiv: &JCAP01(2012)016.

Black hole chemistry: thermodynamics with Lambda  David Kubizňák (Perimeter Institute) 2015 CAP Congress University of Alberta, Edmonton, Canada June.

Entropy localization and distribution in the Hawking radiation Horacio Casini CONICET-Intituto Balseiro – Centro Atómico Bariloche.

２次ゲージ不変摂動論定式化の進行状況 Kouji Nakamura (Grad. Univ. Adv. Stud. (NAOJ)) References : K.N. Prog. Theor. Phys., vol.110 (2003), 723. (gr-qc/ ). K.N. Prog.

Forming Nonsingular Black Holes from Dust Collapse by R. Maier (Centro Brasileiro de Pesquisas Físicas-Rio de Janeiro) I. Damião Soares (Centro Brasileiro.

Holographic Description of Quantum Black Hole on a Computer Yoshifumi Hyakutake (Ibaraki Univ.) Collaboration with M. Hanada （ YITP, Kyoto ）, G. Ishiki.

XVI European Workshop on Strings Theory Madrid– 14 June 2010 arXiv: [hep-th] arXiv: [hep-th] Dumitru Astefanesei, MJR, Stefan Theisen.

BLACK HOLES and WORMHOLES PRODUCTION AT THE LHC I.Ya.Aref’eva Steklov Mathematical Institute, Moscow.

“Einstein Gravity in Higher Dimensions”, Jerusalem, Feb., 2007.

“Models of Gravity in Higher Dimensions”, Bremen, Aug , 2008.

Einstein Field Equations and First Law of Thermodynamics Rong-Gen Cai （蔡荣根） Institute of Theoretical Physics Chinese Academy of Sciences.

Thermodynamics of Apparent Horizon & Dynamics of FRW Spacetime Rong-Gen Cai （蔡荣根） Institute of Theoretical Physics Chinese Academy of Sciences.

Celebrate the 60 th Birthdays of Professors Takashi Nakamura and Kei-ichi Maeda From Rong-Gen Cai.

Rong -Gen Cai ( 蔡荣根） Institute of Theoretical Physics Chinese Academy of Sciences Holography and Black Hole Physics TexPoint fonts used in EMF: AA.

Some Cosmological Consequences of Negative Gravitational Field Energy W. J. Wilson Department of Engineering and Physics University of Central Oklahoma.

Shear viscosity of a highly excited string and black hole membrane paradigm Yuya Sasai Helsinki Institute of Physics and Department of Physics University.

The false vacuum bubble, the true vacuum bubble, and the instanton solution in curved space 1/23 APCTP 2010 YongPyong : Astro-Particle and Conformal Topical.

The false vacuum bubble : - formation and evolution - in collaboration with Chul H. Lee(Hanyang), Wonwoo Lee, Siyong Nam, and Chanyong Park (CQUeST) Based.

General proof of the entropy principle for self-gravitating fluid in static spacetimes 高思杰 (Gao Sijie) 北京师范大学 (Beijing Normal University)

Entanglement Entropy in Holographic Superconductor Phase Transitions Rong-Gen Cai Institute of Theoretical Physics Chinese Academy of Sciences (April 17,

Holographic Superconductors from Gauss-Bonnet Gravity Rong-Gen Cai Institute of Theoretical Physics Chinese Academy of Sciences (May 7, 2012) 2012 海峡两岸粒子物理和宇宙学研讨会,

A Metric Theory of Gravity with Torsion in Extra-dimension Kameshwar C. Wali (Syracuse University) Miami 2013 [Co-authors: Shankar K. Karthik and Anand.

Black holes sourced by a massless scalar KSM2105, FRANKFURT July, 21th 2015 M. Cadoni, University of Cagliari We construct asymptotically flat black hole.

T. Delsate University of Mons-Hainaut Talk included in the Rencontres de Moriond 2009 – La Thuile (Italy).

General Relativity Physics Honours 2008 A/Prof. Geraint F. Lewis Rm 560, A29 Lecture Notes 9.

Department of Physics, National University of Singapore

General proof of the entropy principle for self-gravitating fluid in static spacetimes 高思杰北京师范大学 (Beijing Normal University) Cooperated with 房熊俊

From Black Hole Entropy to the Cosmological Constant Modified Dispersion Relations: from Black Hole Entropy to the Cosmological Constant Remo Garattini.

Gravitational collapse of massless scalar field Bin Wang Shanghai Jiao Tong University.

Holographic QCD in the medium

Black Holes and the Fluctuation Theorem Susumu Okazawa ( 総研大, KEK) with Satoshi Iso and Sen Zhang, arXiv: work in progress.

Entanglement in Quantum Gravity and Space-Time Topology

Yoshinori Matsuo (KEK) in collaboration with Hikaru Kawai (Kyoto U.) Yuki Yokokura (Kyoto U.)

1 Bhupendra Nath Tiwari IIT Kanpur in collaboration with T. Sarkar & G. Sengupta. Thermodynamic Geometry and BTZ black holes This talk is mainly based.

Gravity effects to the Vacuum Bubbles Based on PRD74, (2006), PRD75, (2007), PRD77, (2008), arXiv: [hep-th] & works in preparation.

Based on Phys. Rev. D 92, (R) (2015) 中科大交叉学科理论研究中心

Gauge/gravity duality in Einstein-dilaton theory Chanyong Park Workshop on String theory and cosmology (Pusan, ) Ref. S. Kulkarni,

3 rd Karl Schwarzschild Meeting, Germany 24 July 2017

Thermodynamical behaviors of nonflat Brans-Dicke gravity with interacting new agegraphic dark energy Xue Zhang Department of Physics, Liaoning Normal University,

Equation of State and Unruh temperature

Horizon thermodynamics and Lovelock black holes

Spacetime solutions and their understandings

A no-hair theorem for static black objects in higher dimensions

Formation of universe, blackhole and 1st order phase transition

Thermodynamic Volume in AdS/CFT

A rotating hairy BH in AdS_3

Thermodynamics of accelerating black holes

Charged black holes in string-inspired gravity models

Throat quantization of the Schwarzschild-Tangherlini(-AdS) black hole

Solutions of black hole interior, information paradox and the shape of singularities Haolin Lu.

Based on the work submitted to EPJC

Ruihong Yue Center for Gravity and Cosmology, Yangzhou University

Local Conservation Law and Dark Radiation in Brane Models

Presentation transcript:

Horizon thermodynamics of Lovelock black holes David Kubizňák (Perimeter Institute) Black Holes' New Horizons Casa Matemática Oaxaca, BIRS, Oaxaca, Mexico May 15 – 20, 2016 vs. Pressure of all matter fields

Plan of the talk I.Gravitational dynamics & thermodynamics II.Horizon thermodynamics III.Some remarks a)Free energy & universal thermodynamic behavior b)Lovelock gravity: triple points, isolated critical point c)Why cohomogeneity one? d)Beyond spherical symmetry IV.Summary 1)Devin Hansen, DK, Robert Mann, Universality of P-V criticality in Horizon Thermodynamics, ArXiv: )Devin Hansen, DK, Robert Mann, Criticality and Surface Tension in Rotating Horizon Thermodynamics, Based on:

I) Gravitational dynamics and thermodynamics: some references Black hole thermodynamics: How do the completely classical Einstein equations know about QFT? Sakharov (1967): spacetime emerges as a MF approximation of underlying microscopics, similar to how hydrodynamics emerges from molecular physics. Can we understand gravity from thermodynamic viewpoint? R. G. Cai, Connections between gravitational dynamics and thermodynamics, J. Phys. Conf. Ser. 484 (2014)

Are Einstein equations an equation of state? T. Jacobson, Thermodynamics of space-time: The Einstein equation of state, Phys. Rev. Lett. 75 (1995) 1260, gr-qc/ )Local Rindler horizon: Jacobson’s argument 2)Black hole horizon: “horizon thermodynamics” 3)Apparent horizon in FRW M. Akbar and R.-G. Cai, Thermodynamic Behavior of Friedmann Equations at Apparent Horizon of FRW Universe, Phys. Rev. D75 (2007) , hep-th/ T. Padmanabhan, Classical and quantum thermodynamics of horizons in spherically symmetric space-times, Class. Quant. Grav. 19 (2002) D. Kothawala, S. Sarkar, and T. Padmanabhan, Einstein's equations as a thermodynamic identity: The Cases of stationary axisymmetric horizons and evolving spherically symmetric horizons, Phys. Lett. B652 (2007) 338. new developments: Maulik’s talk

II) Horizon thermodynamics Consider a spherically symmetric spacetime Identify total pressure P with component of energy-momentum tensor evaluated on the horizon Then the radial grav. field equation rewrites as Universal and cohomogeneity-1: with an horizon determined from Horizon equation of state: Horizon first law:

The radial Einstein equation Horizon is a regular null surface Temperature reads Identify the total pressure as We recover the Horizon Equation of State: Black holes in Einstein gravity with volume

Horizon first law Starting from the horizon equation of state let’s identify the entropy as quarter of the area Multiply So we recovered the horizon first law:

Horizon thermodynamics in Einstein gravity The radial Einstein equation where P is identified with Trr component of stress tensor Identification of T, S, and V by other criteria Input: Output: Identification of horizon energy E Universal (matter independent) horizon equations that depend only on the gravitational theory considered (Misner-Sharp mass evaluated on the horizon) End of story!

a) Free energy & Universal thermodynamic behavior Define the Gibbs free energy (Legendre transform of E) Can plot it parametrically using the equation of state III) Some remarks

Only 3 qualitative different cases (considering all possible matter fields - values of P) P<0: RN case P=0: AF case P>0: AdS case (possibly with Q) H-P transition interpretation?

vs. Q=0 charged “Universal” Different ensembles (can. vs. grand can.) Effectively reduces to “vacuum” diagrams Different black holes & environments Universal but the concrete physical interpretation depends on the matter content

b) Generalization to Lovelock gravity Lovelock higher curvature gravity Impose spherically symmetric ansatz Write the radial Lovelock equation where P is identified with Trr component of stress tensor Identify the temperature T via Euclidean trick Identify the true entropy S (Wald) Specify the black hole volume Input:

Output: Identification of horizon energy E Universal (matter independent) horizon equations that depend only on the gravitational theory considered (Misner-Sharp energy evaluated on the horizon, an energy to warp the spacetime and embed the black hole horizon)

Einstein gravity (d=4)

Swallow tails (Gauss-Bonnet gravity d=5)

Triple point (4 th -order Lovelock)

Isolated critical point (3 rd order and higher) Special tuned Lovelock couplings Odd-order J hyperbolic horizons (k=-1) B. Dolan, A. Kostouki, DK, R. Mann, arXiv:

cf. mean field theory critical exponents satisfies Widom relation and Rushbrooke inequality Prigogine-Defay ratio …indicates more than one order parameter? Critical exponents : Comments:

c) Why cohomogeneity one? Consider first vacuum Schwarzschild solution Next take a general solution with general f(r) and g(r) Radial EE + actual Hawking temperature rewrites as horizon equation of state Horizon first law = above (vacuum) first law in terms of true Hawking temperature and Tm.

d) Beyond spherical symmetry Ansatz Identify (cohomogeneity two)

Rewrite the radial Einstein equation where we identified as horizon energy and angular momentum (of vacuum BH) “surface tension”

Rotating horizon thermodynamics Horizon equation of state: Horizon first law: Cohomogeneity two relation Universal regarding the matter content but ansatz has limited applications Provided a volume V of black hole is “freely” specified (not- unique) in canonical ensemble (J=const) we can rewrite these as cohomogeneity one Horizon equation of state: Horizon first law:

Swallow tail: rotating Einstein (P>0)

1)We reviewed the proposal of horizon thermodynamics showing the “equivalence” of thermodynamic first law and radial Einstein equation and extended it to rotating black hole spacetimes. 2)The horizon first law is cohomogeneity one (two in the rotating case) 3)Essentially an “equivalence class” of vacuum first laws (written from a perspective of an observer who measures true temperature) IV) Summary

4)This implies universal thermodynamic behaviour (independent of matter content) that depends only on the gravitational theory in consideration. 5)Interesting phase transitions are observed in Lovelock case (isolated critical point, triple points,..). 6)Compared to the extended phase space thermodynamics of AdS black holes adjusting P more natural? 7)What about a more general rotating ansatz? What is the physical meaning of surface tension sigma?