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Bibliographic Details
Main Authors: Lange, Christian M., Keni, Arya D., Agarwal, Ishita, Daggett, Emma, Mansukhani, Adhyyan S., Kundu, Ankit, Cerjan, Benjamin, Huang, Libai, Hood, Jonathan D.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2506.01917
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author Lange, Christian M.
Keni, Arya D.
Agarwal, Ishita
Daggett, Emma
Mansukhani, Adhyyan S.
Kundu, Ankit
Cerjan, Benjamin
Huang, Libai
Hood, Jonathan D.
author_facet Lange, Christian M.
Keni, Arya D.
Agarwal, Ishita
Daggett, Emma
Mansukhani, Adhyyan S.
Kundu, Ankit
Cerjan, Benjamin
Huang, Libai
Hood, Jonathan D.
contents We implement permanent spectral tuning to bring lifetime-limited emitters into collective resonance within an integrated photonic cavity. This addresses a fundamental challenge in solid-state cavity QED: combining multiple coherent quantum emitters with scalable nanophotonics. Our hybrid approach decouples emitter synthesis from nanophotonic fabrication using straightforward techniques that make cavity QED broadly accessible. High doping densities allow us to couple several coherent emitters to a single cavity mode, while optically-induced frequency shifting provides long-lived spectral control. By tuning two molecules into resonance, we demonstrate controlled formation of collective quantum states, establishing a scalable platform for many-body cavity QED. This opens pathways toward chemically-designed quantum systems where optical properties are engineered through synthetic chemistry.
format Preprint
id arxiv_https___arxiv_org_abs_2506_01917
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Cavity QED with molecular defects coupled to a photonic crystal cavity
Lange, Christian M.
Keni, Arya D.
Agarwal, Ishita
Daggett, Emma
Mansukhani, Adhyyan S.
Kundu, Ankit
Cerjan, Benjamin
Huang, Libai
Hood, Jonathan D.
Quantum Physics
We implement permanent spectral tuning to bring lifetime-limited emitters into collective resonance within an integrated photonic cavity. This addresses a fundamental challenge in solid-state cavity QED: combining multiple coherent quantum emitters with scalable nanophotonics. Our hybrid approach decouples emitter synthesis from nanophotonic fabrication using straightforward techniques that make cavity QED broadly accessible. High doping densities allow us to couple several coherent emitters to a single cavity mode, while optically-induced frequency shifting provides long-lived spectral control. By tuning two molecules into resonance, we demonstrate controlled formation of collective quantum states, establishing a scalable platform for many-body cavity QED. This opens pathways toward chemically-designed quantum systems where optical properties are engineered through synthetic chemistry.
title Cavity QED with molecular defects coupled to a photonic crystal cavity
topic Quantum Physics
url https://arxiv.org/abs/2506.01917