Related papers: Quantum Vacuum in Matter

Quantum Vacuum in Matter

URL: http://arxiv.org/abs/2506.02170v1
Date: Mon, 02 Jun 2025 18:56:09 GMT
Title: Quantum Vacuum in Matter
Authors: Andrey Baydin, Hanyu Zhu, Motoaki Bamba, Kaden Hazzard, Junichiro Kono,
Abstract summary: Quantum field theory states that vacuum is not empty space; it is full of quantum fluctuating electromagnetic fields.<n>This Perspective will first discuss recent experimental and theoretical developments on vacuum-modified condensed matter systems.<n>Then, we will overview some of the most promising cavity designs for enhancing vacuum electromagnetic fields in materials with various energy scales.
Score: 0.3448643277413935
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: An intriguing consequence of quantum field theory is that vacuum is not empty space; it is full of quantum fluctuating electromagnetic fields, or virtual photons, corresponding to their zero-point energy, even though the average number of photons is zero. These short-lived vacuum fluctuations are behind some of the most fascinating physical processes in the universe, including spontaneous emission, the Lamb shift, and the Casimir force. Recent theory and experiments indicate that the properties of materials placed in photonic cavities may be altered, even in the complete absence of any external fields, through interaction with the fluctuating vacuum electromagnetic fields. Judicious engineering of the quantum vacuum surrounding the matter inside a cavity can lead to significant and nonintuitive modifications of electronic and vibrational states, producing a ``vacuum dressed'' material. These exciting new ideas have stimulated discussions regarding the fundamental physics of vacuum-matter interactions and also broadened the scope of potential applications using zero-point fluctuations to engineer materials. This Perspective will first discuss recent experimental and theoretical developments on vacuum-modified condensed matter systems, which usually require the realization of the so-called ultrastrong light-matter coupling regime. Then, we will overview some of the most promising cavity designs for enhancing vacuum electromagnetic fields in materials with various energy scales. Finally, we will discuss urgent open questions and technical challenges to be solved in this emerging field.

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