Complexity of warped conformal field theory

Warped conformal field theories in two dimensions are exotic nonlocal, Lorentz violating field theories characterized by Virasoro-Kac-Moody symmetries and have attracted a lot of attention as candidate boundary duals to warped AdS3 spacetimes, thereby expanding the scope of holography beyond asymptotically AdS spacetimes. Here we investigate WCFT2 s using circuit complexity as a tool. First we compute the holographic volume complexity (CV) which displays a linear UV divergence structure, more akin to that of a local CFT2 and has a very complicated dependence on the Virasoro central charge c and the U(1) Kac-Moody level parameter k. Next we consider circuit complexity based on Virasoro-Kac-Moody symmetry gates where the complexity functional is the geometric (group) action on coadjoint orbits of the Virasoro-Kac-Moody group. We consider a special solution to extremization equations for which complexity scales linearly with time. In the semiclassical limit (large c, k, while c/k remains finite and small) both the holographic volume complexity and circuit complexity scales with k.

Automated summary

Warped conformal field theories in two dimensions, characterized by Virasoro-Kac-Moody symmetries, have been studied as candidate boundary duals to warped AdS3 spacetimes. This study investigates these theories using circuit complexity as a tool and finds that the holographic volume complexity displays a linear UV divergence structure and has a complicated dependence on Virasoro central charge c and U(1) Kac-Moody level parameter k. It also considers circuit complexity based on Virasoro-Kac-Moody symmetry gates and explores a special solution in which complexity scales linearly with time. In the semiclassical limit, both the holographic volume complexity and circuit complexity scale with k.