Comparing numerical evolution with linearisation

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Presentation transcript:

Comparing numerical evolution with linearisation Far-from-equilibrium isotropisation, quasi-normal modes and radial flow Comparing numerical evolution with linearisation Work with Michał Heller, David Mateos, Michał Spalinski, Diego Trancanelli and Miquel Triana References: 1202.0981 (PRL 108) and 1210.xxxx Wilke van der Schee Supervisors: Gleb Arutyunov, Thomas Peitzmann, Koenraad Schalm and Raimond Snellings Workshop Holographic Thermalization, Leiden October 11, 2012

Outline Simple set-up for anisotropy Quasi-normal modes and linearised evolution Radial flow (new results, pictures only) Many states + linearized

Holographic context Simplest set-up: Pure gravity in AdS5 Background field theory is flat Translational- and SO(2)-invariant field theory We keep anisotropy: Caveat: energy density is constant so final state is known P.M. Chesler and L.G. Yaffe, Horizon formation and far-from-equilibrium isotropization in supersymmetric Yang-Mills plasma (2008)

The geometry Symmetry allows metric to be: A, B, S are functions of r and t B measures anisotropy Einstein’s equations simplify Null coordinates Attractive nature of horizon Key differences with Chesler, Yaffe (2008) are Flat boundary Initial non-vacuum state Opposed to Chesler Yaffe approach

The close-limit approximation Early work of BH mergers in flat space Suggests perturbations of an horizon are always small  Linearise evolution around final state (planar-AdS-Schw): Evolution determined by single LDE: R. H. Price and J. Pullin, Colliding black holes: The Close limit (1994)

Quasi-normal mode expansion Solution possible for discrete Imaginary part always positive G.T. Horowitz and V.E. Hubeny, Quasinormal Modes of AdS Black Holes and the Approach to Thermal Equilibrium(1999) J. Friess, S. Gubser, G. Michalogiorgakis, and S. Pufu, Expanding plasmas and quasinormal modes of anti-de Sitter black holes (2006)

First results (Full/Linearized/QNM) Note the QNM-expansion, only 10 complex numbers! Note: initial agreement very unexpected.

Bouncing off the boundary

IR, normal, UV

Statistics of 2000 profiles NOTE: thermalization defined as hydro works Thermalization time is (usually!) very fast: Linear approximation always accurate within “20%”

Recent additions Same linearised calculations with a boost-invariant direction Subtlety: final state is not known initially Add-on: non-homogeneous and includes hydrodynamics Works well  Second and third order corrections The expansion seems to converge Works quite well 

Radial flow Calculation incorporating longitudinal and radial expansion Numerical scheme very similar to colliding shock-waves: Assume boost-invariance on collision axis Assume rotational symmetry (central collision)  2+1D nested Einstein equations in AdS Pressure in transverse plane is not the same P.M. Chesler and L.G. Yaffe, Holography and colliding gravitational shock waves in asymptotically AdS5 spacetime (2010)

Radial flow – initial conditions Two scales: T and size nucleus Energy density is from Glauber model (~Gaussian) No momentum flow (start at t ~ 0.05fm/c) Scale solution such that Metric functions ~ vacuum AdS (not a solution with energy!) H. Niemi, G.S. Denicol, P. Huovinen, E. Molnár and D.H. Rischke, Inﬂuence of the shear viscosity of the quark-gluon plasma on elliptic ﬂow (2011)

Radial flow – results

Radial flow - acceleration Velocity increases rapidly: Acceleration is roughly with R size nucleus Small nucleus reaches maximum quickly

Radial flow – energy profile Energy spreads out:

Radial flow - hydrodynamics Thermalisation is quick, but viscosity contributes

Radial flow - discussion Radial velocity at thermalisation was basically unknown Initial condition is slightly ad-hoc, need more physics? We get reasonable pressures Velocity increases consistently in other runs Results are intuitive Input welcome 

Conclusion Studied (fast!) isotropisation for over 2000 states UV anisotropy can be large, but thermalises fast (though no bound) Linearised approximation works unexpectedly well Works even better for realistic and UV profiles Numerical scheme provides excellent basis Radial flow, fluctuations, elliptic flow What happens universally? What is the initial state?