Entangled Quantum Negative Energy Teleportation as a Probe of Semiclassical Gravity

TL;DR

This paper explores how quantum energy teleportation can generate detectable spacetime curvature, proposing experimental methods to observe semiclassical gravity effects using quantum technologies.

Contribution

It introduces a realistic framework for generating and detecting negative energy densities via QET, and proposes new strategies and models for laboratory tests of semiclassical gravity.

Findings

Computed signal-to-noise ratios for detecting Ricci curvature.

Proposed synchronization and squeezing strategies to enhance detection.

Introduced the Quantum-Curvature Compression Channel as an alternative to warp-drive geometries.

Abstract

We investigate the generation of semiclassical spacetime curvature via localized negative energy densities created by quantum energy teleportation (QET) and Casimir-enhanced confinement. Using realistic noise models and experimental architectures, we compute signal-to-noise ratios for detecting the resulting Ricci curvature via atomic clocks, interferometry, and optomechanical strain readout. We propose synchronization and squeezing strategies to enhance detectability and simulate spatial curvature profiles from focused QET pulses. Finally, we introduce a speculative framework -- the Quantum-Curvature Compression Channel -- as an experimentally motivated alternative to warp-drive geometries, enabling apparent geodesic compression through synchronized quantum energy operations. Our results clarify the experimental path toward laboratory tests of exotic stress-energy and semiclassical gravity effects.