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Main Authors: Bretscher, Hope M, Graziotto, Lorenzo, Michael, Marios H, Montanaro, Angela, Lu, I-Te, Grankin, Andrey, McIver, James W, Faist, Jerome, Fausti, Daniele, Eckstein, Martin, Ruggenthaler, Michael, Rubio, Angel, Basov, DN, Hafezi, Mohammad, Claassen, Martin, Kennes, Dante M, Sentef, Michael A
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.08666
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author Bretscher, Hope M
Graziotto, Lorenzo
Michael, Marios H
Montanaro, Angela
Lu, I-Te
Grankin, Andrey
McIver, James W
Faist, Jerome
Fausti, Daniele
Eckstein, Martin
Ruggenthaler, Michael
Rubio, Angel
Basov, DN
Hafezi, Mohammad
Claassen, Martin
Kennes, Dante M
Sentef, Michael A
author_facet Bretscher, Hope M
Graziotto, Lorenzo
Michael, Marios H
Montanaro, Angela
Lu, I-Te
Grankin, Andrey
McIver, James W
Faist, Jerome
Fausti, Daniele
Eckstein, Martin
Ruggenthaler, Michael
Rubio, Angel
Basov, DN
Hafezi, Mohammad
Claassen, Martin
Kennes, Dante M
Sentef, Michael A
contents Coupling tailored electromagnetic fluctuations to materials provides a resource for controlling correlated quantum matter. By structuring the frequency, spatial, and modal distribution of fluctuations through a new generation of cavity quantum materials, vacuum and thermal spectra can shift phase boundaries and stabilize or suppress orders. This review organizes the field around a fluctuation-focused perspective, surveying a practical design toolbox and recent milestones, and outlining theory-experiment challenges in realistic, multimode, beyond-long-wavelength regimes. We highlight photonic observables and map opportunities for equilibrium and driven control across superconducting, magnetic, moire, and topological platforms.
format Preprint
id arxiv_https___arxiv_org_abs_2604_08666
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Fluctuation engineering in cavity quantum materials
Bretscher, Hope M
Graziotto, Lorenzo
Michael, Marios H
Montanaro, Angela
Lu, I-Te
Grankin, Andrey
McIver, James W
Faist, Jerome
Fausti, Daniele
Eckstein, Martin
Ruggenthaler, Michael
Rubio, Angel
Basov, DN
Hafezi, Mohammad
Claassen, Martin
Kennes, Dante M
Sentef, Michael A
Mesoscale and Nanoscale Physics
Strongly Correlated Electrons
Quantum Physics
Coupling tailored electromagnetic fluctuations to materials provides a resource for controlling correlated quantum matter. By structuring the frequency, spatial, and modal distribution of fluctuations through a new generation of cavity quantum materials, vacuum and thermal spectra can shift phase boundaries and stabilize or suppress orders. This review organizes the field around a fluctuation-focused perspective, surveying a practical design toolbox and recent milestones, and outlining theory-experiment challenges in realistic, multimode, beyond-long-wavelength regimes. We highlight photonic observables and map opportunities for equilibrium and driven control across superconducting, magnetic, moire, and topological platforms.
title Fluctuation engineering in cavity quantum materials
topic Mesoscale and Nanoscale Physics
Strongly Correlated Electrons
Quantum Physics
url https://arxiv.org/abs/2604.08666