Disconnecting a Traversable Wormhole: Universal Quench Dynamics in Random Spin Models

TL;DR

This paper uses holographic duality to connect gravity physics with experimental quench dynamics in random spin models, revealing universal features like slow decay and oscillations linked to wormhole disconnection.

Contribution

It demonstrates how gravity duality explains universal magnetization dynamics in quantum spin models, unifying experimental observations through wormhole physics.

Findings

Universal slow decay and oscillations in magnetization dynamics.

Gravity duality maps quench dynamics to wormhole disconnection.

Insights help unify different quantum system experiments.

Abstract

Understanding strongly interacting quantum matter and quantum gravity are both important open issues in theoretical physics, and the holographic duality between quantum field theory and gravity theory nicely brings these two topics together. Nevertheless, direct connections between gravity physics and experimental observations in quantum matter are still rare. Here we utilize the gravity physics picture to understand quench dynamics experimentally observed in a class of random spin models realized in several different quantum systems, where the dynamics of magnetization are measured after the external polarization field is suddenly turned off. Two universal features of the magnetization dynamics, namely, a slow decay described by a stretched exponential function and an oscillatory behavior, are respectively found in different parameter regimes across different systems. This work addresses the issues of generic conditions under which these two universal features can occur, and we find that a natural answer to this question emerges in the gravity picture. By the holographic duality bridged by a model proposed by Maldacena and Qi, the quench dynamics after suddenly turning off the external polarization field is mapped to disconnecting an eternal traversable wormhole. Our studies show that insight from gravity physics can help unifying different experiments in quantum systems.