Journal of High Energy Physics (Aug 2024)
Null states and time evolution in a toy model of black hole dynamics
Abstract
Abstract Spacetime wormholes can provide non-perturbative contributions to the gravitational path integral that make the actual number of states e S in a gravitational system much smaller than the number of states e S p $$ {e}^{S_{\textrm{p}}} $$ predicted by perturbative semiclassical effective field theory. The effects on the physics of the system are naturally profound in contexts in which the perturbative description actively involves N = O(e S ) of the possible e S p $$ {e}^{S_{\textrm{p}}} $$ perturbative states; e.g., in late stages of black hole evaporation. Such contexts are typically associated with the existence of non-trivial quantum extremal surfaces. However, by forcing a simple topological gravity model to evolve in time, we find that such effects can also have large impact for N ≪ e S (in which case no quantum extremal surfaces can arise). In particular, even for small N, the insertion of generic operators into the path integral can cause the non-perturbative time evolution to differ dramatically from perturbative expectations. On the other hand, this discrepancy is small for the special case where the inserted operators are non-trivial only in a subspace of dimension D ≪ e S . We thus study this latter case in detail. We also discuss potential implications for more realistic gravitational systems.
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