Abstract
It is generally agreed that black hole formation in gravity corresponds to thermalization in the dual CFT. It is sometimes argued that if the CFT evolution shows evidence of large redshift in gravity, then we have seen black hole formation in the CFT. We argue that this is not the case: a clock falling towards the horizon increases its redshift but remains intact as a clock; thus it is not ‘thermalized’. Instead, thermalization should correspond to a new phase after the phase of large redshift, where the infalling object turns into fuzzballs on reaching within planck distance of the horizon. We compute simple examples of the scattering vertex in the D1D5 CFT which, after many iterations, would lead to thermalization. An initial state made of two left-moving and two right-moving excitations corresponds, in gravity, to two gravitons heading towards each other. The thermalization vertex in the CFT breaks these excitations into multiple excitations on the left and right sides; we compute the amplitudes for several of these processes. We find secular terms that grow as t2 instead of oscillating with t; we conjecture that this may be a feature of processes leading to thermalization.
Highlights
The AdS/CFT correspondence [1,2,3] gives a remarkable map between gravity in AdS space and a CFT without gravity
It is generally agreed that black hole formation in gravity corresponds to thermalization in the dual CFT
Thermalization should correspond to a new phase after the phase of large redshift, where the infalling object turns into fuzzballs on reaching within planck distance of the horizon
Summary
The AdS/CFT correspondence [1,2,3] gives a remarkable map between gravity in AdS space and a CFT without gravity In this correspondence, black hole formation in gravity is expected to map to thermalization in the dual CFT [3]. As it gets closer and closer to the horizon, its redshift becomes larger and larger. From this fact one might at first think that if we encounter a large redshift in the CFT, we are seeing thermalization. We will perform a weak coupling computation in the CFT which we argue gives a signal for actual thermalization, albeit in a very simplified setting since we take parameters of the theory where the black hole is very small.
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