Measuring space-time curvature using maximally path-entangled quantum states

TL;DR

This paper proposes a quantum optical method using maximally path-entangled states to measure space-time curvature, enhancing sensitivity to gravitational effects and potentially reducing experimental requirements.

Contribution

It introduces a novel quantum interferometry technique employing entangled light to directly measure components of the Riemann curvature tensor.

Findings

Entanglement increases sensitivity to gravitational phases.

Measurement of gravity gradients can be performed with reduced height differences.

The method improves detection of space-time curvature using quantum states.

Abstract

Experiments at the interface of quantum field theory and general relativity would greatly benefit theoretical research towards their unification. The gravitational aspects of quantum experiments performed so far can be explained either within Newtonian gravity or by Einstein's equivalence principle. Here, we describe a way to measure components of the Riemann curvature tensor with maximally path-entangled quantum states of light. We show that the entanglement-induced increase in sensitivity also holds for gravitationally-induced phases in Mach-Zehnder interferometers. As a result, the height difference between the two interferometer arms necessary to rule out flat space-time by measuring gravity gradients can be significantly reduced.