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Autor principal: Davoodi, Fatemeh
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2506.12805
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author Davoodi, Fatemeh
author_facet Davoodi, Fatemeh
contents Long lived coherent quasiparticles are a promising foundation for novel quantum technologies, where maintaining quantum coherence is crucial. Decoherence, driven by finite emitter lifetimes, remains a central challenge in quantum computing. Here, we control the dynamics of spatially separated quantum emitters via preserving their phase information by introducing a topological waveguide as a robust chiral reservoir. Incoherent quantum emitters randomly positioned near a perturbed honeycomb plasmonic interface and couple to the mutual topological interface mode. Using the S3 Stokes parameter, we trace farfield polarization patterns that reflect emitter coherence and spin-momentum locking. We show that even weakly coupled emitters exhibit coherent excitation and imprint phase on the emission. Time domain dynamics reveal signatures of superradiance and subradiance that correlate with spatial interference in S3. These spatial temporal features confirm that the observed polarization patterns arise from coherent quantum manybody dynamics, not classical interference. This challenges the conventional dichotomy between incoherent and coherent regimes, revealing that topological chiral photonic environments mediate long-range quantum correlations beyond standard waveguide QED.
format Preprint
id arxiv_https___arxiv_org_abs_2506_12805
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Beyond Decoherence: Control the Collective Quantum Dynamics of Quasi Particles in Topological Interface
Davoodi, Fatemeh
Optics
Long lived coherent quasiparticles are a promising foundation for novel quantum technologies, where maintaining quantum coherence is crucial. Decoherence, driven by finite emitter lifetimes, remains a central challenge in quantum computing. Here, we control the dynamics of spatially separated quantum emitters via preserving their phase information by introducing a topological waveguide as a robust chiral reservoir. Incoherent quantum emitters randomly positioned near a perturbed honeycomb plasmonic interface and couple to the mutual topological interface mode. Using the S3 Stokes parameter, we trace farfield polarization patterns that reflect emitter coherence and spin-momentum locking. We show that even weakly coupled emitters exhibit coherent excitation and imprint phase on the emission. Time domain dynamics reveal signatures of superradiance and subradiance that correlate with spatial interference in S3. These spatial temporal features confirm that the observed polarization patterns arise from coherent quantum manybody dynamics, not classical interference. This challenges the conventional dichotomy between incoherent and coherent regimes, revealing that topological chiral photonic environments mediate long-range quantum correlations beyond standard waveguide QED.
title Beyond Decoherence: Control the Collective Quantum Dynamics of Quasi Particles in Topological Interface
topic Optics
url https://arxiv.org/abs/2506.12805