English

Cavity engineering of solid-state materials without external driving

Materials Science 2025-05-29 v1 Optics Quantum Physics

Abstract

Confining electromagnetic fields inside an optical cavity can enhance the light-matter coupling between quantum materials embedded inside the cavity and the confined photon fields. When the interaction between the matter and the photon fields is strong enough, even the quantum vacuum field fluctuations of the photons confined in the cavity can alter the properties of the cavity-embedded solid-state materials at equilibrium and room temperature. This approach to engineering materials with light avoids fundamental issues of laser-induced transient matter states. To clearly differentiate this field from phenomena in driven systems, we call this emerging field cavity materials engineering. In this review, we first present theoretical frameworks, especially, ab initio methods, for describing light-matter interactions in solid-state materials embedded inside a realistic optical cavity. Next, we overview a few experimental breakthroughs in this domain, detailing how the ground state properties of materials can be altered within such confined photonic environments. Moreover, we discuss state-of-the-art theoretical proposals for tailoring material properties within cavities. Finally, we outline the key challenges and promising avenues for future research in this exciting field.

Keywords

Cite

@article{arxiv.2502.03172,
  title  = {Cavity engineering of solid-state materials without external driving},
  author = {I-Te Lu and Dongbin Shin and Mark Kamper Svendsen and Simone Latini and Hannes Hübener and Michael Ruggenthaler and Angel Rubio},
  journal= {arXiv preprint arXiv:2502.03172},
  year   = {2025}
}

Comments

75 pages, 8 figures

R2 v1 2026-06-28T21:33:27.717Z