Rhodium Mossbauer Superradiance of Observable Gravitational Effect

TL;DR

This paper reports experimental observations of rhodium Mossbauer superradiance showing potential gravitational effects, with implications for gravitational wave detection and gamma laser development, by analyzing photonic band gaps and superradiance phenomena.

Contribution

It presents novel experimental evidence linking Mossbauer superradiance in rhodium to observable gravitational effects, advancing understanding of photon-matter interactions in gravitational fields.

Findings

Observation of superradiance corresponding to Earth's gravity

Manifestation of photonic band gap similar to superconducting gap

Potential applications in gravitational wave detection and gamma laser technology

Abstract

We summarize the experimental observations of three case studies on the long-lived rhodium Mossbauer Effect. Extraordinary observations reported in this work manifest the open-up of photonic band gap in analogy to the superconducting gap. Observable gravitational effect is manifested by the superradiance of different sample orientations corresponding to the earth gravity. These observations are of potential importance for detecting gravitational waves and development of the two-photon gamma laser.