`Seeing' the quantum ripples of spacetime
TLDR
This paper proposes a novel tabletop method for detecting gravitons by observing photon emission from quantum harmonic oscillators in a pumped cavity.
Key contributions
- Proposes a novel tabletop method for detecting gravitons.
- Utilizes charged quantum harmonic oscillators within a photon-pumped cavity.
- Graviton absorption leads to photon emission, while graviton emission causes photon absorption.
- Transition probabilities are enhanced by pumping photons, enabling a simple detector.
Why it matters
This paper offers a novel, potentially feasible tabletop method for detecting gravitons, which are notoriously difficult to observe. By visualizing graviton effects through photon interactions, it opens new avenues for experimental quantum gravity research.
Original Abstract
We propose a novel way of detecting gravitons using emission of photons from charged array of quantum harmonic oscillators placed inside of a cavity while the cavity is being pumped with low frequency photons. We observe that when the detector is in its ground state, a single graviton is absorbed by the detector while it jumps a single energy level by simultaneously emitting a photon. We also observe that while the detector de-excites from an higher energy level, it spontaneously emits a high frequency graviton, by absorbing a single photon. This analytical outcome encourages us to propose a very simple tabletop graviton detector model as the transition probabilities can be significantly enhanced by pumping photons in the initial state of the system. This mechanism gives us a physical way to `visualize' the effect of gravitons with a relativistic system.
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