Spacetime emergence via holographic RG flow from incompressible Navier-Stokes at the horizon. based on

Similar documents
Fluid/Gravity Correspondence for general non-rotating black holes

Holographic relations at finite radius

Towards new relativistic hydrodynamcis from AdS/CFT

Quasilocal notions of horizons in the fluid/gravity duality

QUANTUM QUENCH ACROSS A HOLOGRAPHIC CRITICAL POINT

Boost-invariant dynamics near and far from equilibrium physics and AdS/CFT.

The black hole membrane paradigm redux

AdS/CFT and holographic superconductors

Holography and (Lorentzian) black holes

Insight into strong coupling

Black Holes, Fluids, and their Instabilities. Roberto Emparan ICREA & U. Barcelona

Insight into strong coupling

Talk based on: arxiv: arxiv: arxiv: arxiv: arxiv:1106.xxxx. In collaboration with:

A toy model for the Kerr/CFT. correspondence

Out of equilibrium dynamics and Robinson-Trautman spacetimes. Kostas Skenderis

Emergent Quantum Criticality

Shock waves in strongly coupled plasmas

Towards holographic heavy ion collisions

Holography and the (Exact) Renormalization Group

Nonlinear Fluid Dynamics from Gravity

Topologically Massive Gravity and AdS/CFT

AdS/CFT and Second Order Viscous Hydrodynamics

Fefferman Graham Expansions for Asymptotically Schroedinger Space-Times

Nonlinear Fluid Dynamics from Gravity

Holography and Unitarity in Gravitational Physics

Introduction to AdS/CFT

Quark-gluon plasma from AdS/CFT Correspondence

Quantum Gravity. Juan Maldacena. Institute for Advanced Study

5. a d*, Entanglement entropy and Beyond

Duality and Holography

Principles of Hydrodynamics Fluid/Gravity Correspondence The Entropy Current Outlook. The Entropy Current. Yaron Oz (Tel-Aviv University)

Effective field theory, holography, and non-equilibrium physics. Hong Liu

Holographic entropy production

The Cardy-Verlinde equation and the gravitational collapse. Cosimo Stornaiolo INFN -- Napoli

Holography with Shape Dynamics

The Fluid/Gravity Correspondence

SYMMETRIES AND DISSIPATIVE MAGNETOHYDRODYNAMICS

A SOLITON MENAGERIE IN ADS Mukund Rangamani Durham University

Anisotropic Hydrodynamics, Chiral Magnetic Effect and Holography

Black Holes and Quantum Mechanics

Strongly coupled plasma - hydrodynamics, thermalization and nonequilibrium behavior

TOWARDS WEAK COUPLING IN HOLOGRAPHY

Quantum mechanics and the geometry of spacetime

Holography for non-relativistic CFTs

Lifshitz Hydrodynamics

From Petrov-Einstein to Navier-Stokes

Holographic Wilsonian Renormalization Group

Towards a holographic formulation of cosmology

AdS/CFT and condensed matter physics

Local RG, Quantum RG, and Holographic RG. Yu Nakayama Special thanks to Sung-Sik Lee and Elias Kiritsis

Large D Black Hole Membrane Dynamics

The Gauge/Gravity correspondence: linking General Relativity and Quantum Field theory

Stress tensor correlators from holography

Differential relations for fluid flow

Gauge/Gravity Duality: Applications to Condensed Matter Physics. Johanna Erdmenger. Julius-Maximilians-Universität Würzburg

Non-relativistic holography

Status of the viscosity bound

RELG - General Relativity

Effective Field Theory of Dissipative Fluids

Kyung Kiu Kim(Kyung-Hee University, CQUeST) With Youngman Kim(APCTP), Ik-jae Sin(APCTP) and Yumi Ko(APCTP)

Trans-series & hydrodynamics far from equilibrium

Lifshitz Geometries in String and M-Theory

Bjorken flow from an AdS Schwarzschild black hole GEORGE SIOPSIS. Department of Physics and Astronomy The University of Tennessee

Holography for Black Hole Microstates

Manifestly diffeomorphism invariant classical Exact Renormalization Group

Holographic renormalization and reconstruction of space-time. Kostas Skenderis Southampton Theory Astrophysics and Gravity research centre

Second law of black-hole thermodynamics in Lovelock theories of gravity

Entanglement, geometry and the Ryu Takayanagi formula

Introductory Course on Black Hole Physics and AdS/CFT Duality Lecturer: M.M. Sheikh-Jabbari

Anomalous hydrodynamics and gravity. Dam T. Son (INT, University of Washington)

Non-relativistic AdS/CFT

A Holographic Description of Black Hole Singularities. Gary Horowitz UC Santa Barbara

arxiv: v1 [nucl-th] 9 Jun 2008

Yun Soo Myung Inje University

5.5 Energy-momentum tensor

HOLOGRAPHIC RECIPE FOR TYPE-B WEYL ANOMALIES

Holographic methods for cosmology. Gonzalo Torroba Stanford University

Some Comments on Relativistic Hydrodynamics, Fuzzy Bag Models for the Pressure, and Early Space-Time Evolution of the QCD Matter

BLACK HOLES IN 3D HIGHER SPIN GRAVITY. Gauge/Gravity Duality 2018, Würzburg

On the deformed Einstein equations and quantum black holes

Non-Equilibrium Steady States Beyond Integrability

Analog Duality. Sabine Hossenfelder. Nordita. Sabine Hossenfelder, Nordita Analog Duality 1/29

Department of Physics

Zero Temperature Dissipation & Holography

Lecture Notes on General Relativity

Gravity & Hydrodynamics

Towards a 2nd Law for Lovelock Theory

Braneworlds: gravity & cosmology. David Langlois APC & IAP, Paris

Holography, thermalization and heavy-ion collisions I

10 Interlude: Preview of the AdS/CFT correspondence

Excluding Black Hole Firewalls with Extreme Cosmic Censorship

Counterterms, critical gravity and holography

Holographic Cosmology Beyond Inflation? Mark Trodden! University of Pennsylvania

Dynamics, phase transitions and holography

Attempts at vacuum counterexamples to cosmic censorship in AdS. Abstract

Rigid Holography and 6d N=(2,0) Theories on AdS 5 xs 1

HIGHER SPIN ADS 3 GRAVITIES AND THEIR DUAL CFTS

κ = f (r 0 ) k µ µ k ν = κk ν (5)

Applied Gravity. Shiraz Minwalla. IISER, Nov Department of Theoretical Physics Tata Institute of Fundamental Research, Mumbai.

Geometrical Approximation to the AdS/CFT Correspondence

Transcription:

Prifysgol Abertawe? Strong Fields, Strings and Holography Spacetime emergence via holographic RG flow from incompressible Navier-Stokes at the horizon based on arxiv:1105.4530 ; arxiv:arxiv:1307.1367 with Ayan Mukhopadhyay

References.

Holography - there is always the radial coordinate Henningson, Skenderis:Balasubramanian, Kraus; de Boer, Verlinde,, Verlinde 1. Is it a renormalization scale? Heemskerk, Polchinski; Faulkner, Liu, Rangamani 2. If yes, why the radial evolution is not a first order ODE? 3. Can we build space-time (metric) from a holographic RG flow? 4. The fluid/gravity correspondence (boosted black branes in AdS) Policastro,Son, Starinetz; Bhattacharyya, Hubeny, Minwalla, Rangamani; Baier, Romatschke, Son, Starinets, Stephanov Non-relativistic incompressible Navier-Stokes Horizon Conformal fluid Boundary Damour; Eling,Fouxon, Oz; Bredberg, Keeler, Lysov, Strominger Hydrodynamic RG flow?!

1. Motivation 2. A brief introduction to fluid mechanics 3.The Ansatz 4.The hypersurface foliation 5. Einstein's equations of motion 6. The renormalized energy-momentum tensor 7. How to eliminate (and reconstract) the metric? 8. RG flow of the thermodynamic data 9. Horizon fluid 10. Results

A very brief introduction to fluid mechanics I - Basic data: weakly curved - The energy-momentum tensor: - Conservation of the EM tensor is the EoM: - Thermodynamics: - The speed of sound:

A very brief introduction to fluid mechanics II - Equilibrium: - Euler equations: - Non-equilibrium EM tensor scalars number of derivatives orthogonal vectors - What can we built on-shell at n=1? traceless orthogonal tensors symmetric and traceless

A very brief introduction to fluid mechanics III - Scalars, Vectors and Tensors for n=2: 7 scalars, 6 vectors and 8 tensors

A very brief introduction to fluid mechanics IV - Landau-Lifshitz frame: local velocity of energy transport or - The full hydrodynamic EM tensor has no vector terms: shear bulk viscosity

A very brief introduction to fluid mechanics V - Conformal fluid (Weyl covariance): 1. No scalars 2. Only 5 tensors at n=2 - Conformal fluid dual to Einstein gravity: Bhattacharyya, Hubeny,Minwalla, Rangamani; Baier, Romatschke, Son, Starinets, Stephanov

The Ansatz Overall parameteres to fix! 1. The hydrodinamical variables have to be redefined at every hypersurface: 2. There is no need to find an explicit solution. 3. Instead: It works! No metric needed 4. All the parameters here are auxiliery. 5. The transport coefficients in the hydrodynamic EM tensor are physical:

The hypersurface foliation Fefferman-Graham possible to eliminate the metric Eddington-Finkelstein impossible to eliminate the metric The radial coordinate corresponds to the RG scale Regular at the boundary, singular at the horizon Regular at the horizon, singular at the boundary 1. We are interested only in the transport coefficients EF FG 2. The conformality is more difficult to guarantee Boundary Horizon

Einstein's equations of motion dynamical constrain constrain First order Einstein's equation!

The renormalized energy-momentum tensor - Dirichlet boundary conditions: Brown-York fixed at the boundary Einstein tensor counter-terms Q: Can we really use Dirichlet BC? A1: Yes, because we don't specify the metric... A2: We can avoid using Dirichlet BC! It is only sufficient to assume that: See later... 1. Universality, the EM tensor is conserved for any solution 2. The bare EM tensor staisfies the junction condition (BY is the only option) 3. The dependence on lads comes only via an overall dimensionless factor

How to eliminate the metric? 1. We can express 2. in terms of can be eliminated from Einstein's equation 3. What should we do with the r-derivatives of the Ricci tensor?

How to eliminate the metric (cont.)? Just one more example: Euler equations

RG flow of the thermodynamic data (Late time) horizon Requiring finite energy at the horizon Using the thermodynamical equations: Can be fixed from the Hawking temperature

Reconstruction of the metric 1.Choose the boundary conditions for the metric, u and T 2.Write a new Ansatz for the metric, u and T 3.Solve the old Ansatz for u' and T' 4.And:

Do we have enough equations? 1a.Traceless orthogonal part of Einstein's equation: 1b.Vector part 1c.Two scalar components and 2.Norm condition We get the same number of independent equations (algebraic and differential) as the number of variables ODEs

The horizon fluid I - The temperature is infinite on the horizon. Themodynamics breaks down. - The pressure and the speed of sound blow up as well. Near horizon rescaling! - The fluid EOMs become regular. - At the first order the horizon fluid is now an RG flow fixed point, provided the viscosities are finite. - This fluid is incompressible Navier-Stokes. - Higher order transport coefficients (TC) do not destroy this fixed point. - Unique way to solve the first order (beta-)equations for the higher TCs.

The horizon fluid II Eling,Fouxon, Oz; Bredberg, Keeler, Lysov, Strominger; Bhattacharyya, Minwalla, Wadia In the local inertial frame of an infalling observer: The thermodynamic parameters rescale as follows: mass density

The horizon fluid III If the viscosities are finite: Incompressible... Navier-Stokes The near horizon rescaling becomes a symmetry : RG flow fixed point Additional NH rescaling Boundary Horizon

The horizon fluid IV What near horizon behaviour of the 2nd order transport coefficient preserves the incompressible Navier-Stokes RG flow fixed point? We know how these tensors scale! See later on

The horizon fluid V and the scalar TCs: Easy to extend to higher orders!

The results:1st order transport coeff. (TC) Shear Viscosity Cannot be fixed at the 1st order! Bulk Viscosity Otherwise no incompressbile NS at the horizon!

The results: 2nd order (Tensors and Scalars) It can be easily shown that:

2nd order Tensor TC (continued) The «homogeneous» solution behaves like The solution can be determined uniquely if we require «regularity»: monotonically decreasing function Bhattacharyya, Hubeny,Minwalla, Rangamani; Baier, Romatschke, Son, Starinets, Stephanov

2nd order Tensor TC (still continued) The «homogeneous» solution is «regular» Can we nevertheless fix the integration constant?

2nd order Tensor TC (just two more slides) const Unless Very unlikely! Three orders to cancel only with

2nd order Tensor TC (almost the last slide) «Magically» it works: Fixed only at the 2nd order! - Similarly for - Higher orders needed for - Conformality at the boundary (appear together in one conformal tensor)

2nd order Scalar TC

Future directions 1. Higher orders 2. Can we determine all counterterms from the horizon? 3. Stationary black holes (and other setups) 4. Other bulk fields (vectors, fermions,...) 5. Non-relativistic fluid (on any hypersurface) 6. Turbulence

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback