Chaos and the reparametrization mode on the AdS2 string

We study the holographic correlators corresponding to scattering of fluctuations of an open string worldsheet with AdS(2) geometry. In the out-of-time-order configuration, the correlators display a Lyapunov growth that saturates the chaos bound. We show that in a double-scaling limit interpolating between the Lyapunov regime and the late time exponential decay, the out-of-time-order correlator (OTOC) can be obtained exactly, and it has the same functional form found in the analogous calculation in JT gravity. The result can be understood as coming from high energy scattering near the horizon of a AdS2 black hole, and is essentially controlled by the flat space worldsheet S-matrix. While previous works on the AdS2 string employed mainly a static gauge approach, here we focus on conformal gauge and clarify the role of boundary reparametrizations in the calculation of the correlators. We find that the reparametrization mode is governed by a non-local action which is distinct from the Schwarzian action arising in JT gravity, and in particular leads to SL(2, R) invariant boundary correlators. The OTOC in the double-scaling limit, however, has the same functional form as that obtained from the Schwarzian, and it can be computed using the reparametrization action and resumming a subset of diagrams that are expected to dominate in the limit. One application of our results is to the defect CFT defined by the half-BPS Wilson loop in N = 4 SYM. In this context, we show that the exact result for the OTOC in the double-scaling limit is in precise agreement with a recent analytic bootstrap prediction to three-loop order at strong coupling.

Automated summary

This study investigates the holographic correlators corresponding to scattering of fluctuations of an open string worldsheet with AdS(2) geometry, and finds that in the out-of-time-order configuration, the correlators display a Lyapunov growth that saturates the chaos bound. By utilizing a double-scaling limit, the exact form of the out-of-time-order correlator (OTOC) can be obtained, which is found to have the same functional form as the analogous calculation in JT gravity.