Quantum Simulation of Coherent Hawking-Unruh Radiation

TL;DR

This paper demonstrates the quantum simulation of Hawking-Unruh radiation using a Bose-Einstein condensate, revealing coherent matter-wave pairs and confirming theoretical predictions about thermal radiation in curved spacetime.

Contribution

It introduces a novel experimental approach to simulate Hawking-Unruh radiation with a Bose-Einstein condensate, providing new insights into quantum effects in curved spacetime.

Findings

Observation of coherent atom pairs with opposite momenta

Matterwave distribution follows a Boltzmann distribution consistent with Unruh temperature

Long-distance phase coherence and reversibility of emitted matter-waves

Abstract

Exploring quantum phenomena in a curved spacetime is an emerging interdisciplinary area relating many fields in physics such as general relativity, thermodynamics, and quantum information. One famous prediction is the Hawking-Unruh thermal radiation, the manifestation of Minkowski vacuum in an accelerating reference frame. We simulate the radiation by evolving a parametrically driven Bose-Einstein condensate of $\approx 10^5$ atoms, which radiates coherent pairs of atoms with opposite momenta. We observe a matterwave field which follows a Boltzmann distribution for a local observer. The extracted temperature and entropy from the atomic distribution are in agreement with Unruh's predictions. We further observe the long-distance phase coherence and temporal reversibility of emitted matter-waves, hallmarks that distinguish Unruh radiations from classical counterparts. Our results may lead to further insights regarding the nature of the Hawking and Unruh effects and behaviors of quantum physics in a curved spacetime.