Direct Imaging of Weak‐to‐Strong‐Coupling Dynamics in Biological Plasmon–Exciton Systems

Yuan, Zhiyi; Huang, Shih‐Hsiu; Qiao, Zhen; Gong, Chen; Liao, Yikai; Kim, Munho; Birowosuto, Muhammad Danang; Dang, Cuong; Wu, Pin Chieh; Chen, Yu Cheng

doi:10.1002/lpor.202200016

Cited by 3 publications

(2 citation statements)

References 58 publications

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“…This was achieved by measuring PRET induced by quantum biological electron tunneling (QBET) from a plasmonic nanoparticle to adjacent biomolecules. However, a few studies have focused on the quantum electrodynamics of strong coupling phenomena with biomaterials , …”

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confidence: 99%

Quantum Electrodynamic Behavior of Chlorophyll in a Plasmonic Nanocavity

Kokin

Koo

et al. 2022

Nano Lett.

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Plasmonic nanocavities have been used as a novel platform for studying strong light−matter coupling, opening access to quantum chemistry, material science, and enhanced sensing. However, the biomolecular study of cavity quantum electrodynamics (QED) is lacking. Here, we report the quantum electrodynamic behavior of chlorophyll-a in a plasmonic nanocavity. We construct an extreme plasmonic nanocavity using Au nanocages with various linker molecules and Au mirrors to obtain a strong coupling regime. Plasmon resonance energy transfer (PRET)-based hyperspectral imaging is applied to study the electrodynamic behaviors of chlorophyll-a in the nanocavity. Furthermore, we observe the energy level splitting of chlorophyll-a, similar to the cavity QED effects due to the light− matter interactions in the cavity. Our study will provide insight for further studies in quantum biological electron or energy transfer, electrodynamics, the electron transport chain of mitochondria, and energy harvesting, sensing, and conversion in both biological and biophysical systems.

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confidence: 99%

Quantum Electrodynamic Behavior of Chlorophyll in a Plasmonic Nanocavity

Kokin

Koo

et al. 2022

Nano Lett.

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“…However, mode splitting in scattering spectra can be caused by two mechanisms: Rabi splitting at strong coupling and Fano resonance at weak coupling. [15,26,33,[46][47][48] Therefore, it is still questionable to determine the strong coupling from scattering results alone. The absorption spectrum is considered a more accurate method.…”

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confidence: 99%

Real‐Time Tuning Exciton‐Plasmon Coupling with Photosensitive Nanocavity

Han,

He,

Zhao

et al. 2023

Advanced Optical Materials

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A novel method is proposed to directly characterize the exciton‐plasmon coupling in a photosensitive nanoparticle‐on‐mirror (NPoM) nanocavity. Under the illumination of UV light, the localized surface plasmon resonance (LSPR) peaks of the nanocavity can be continuously tuned over a wide range (≈65 nm), enabling precise determination of the energy dispersion relationship of plexcitons in the nanocavity. The results indicate that the energy of Rabi splitting can be actively tuned from 65 meV (weak coupling) to 170 meV (strong coupling) by adjusting the LSPR peak of a specific nanocavity (particle size L≈55‐92 nm) to the exciton wavelength (the zero detuning). In addition, the criterion of strong coupling is optimized by introducing single‐particle absorption spectroscopy. The work offers an intuitive method for the strong coupling characterization in nanocavity, paving the way for the real‐time tuning of coupling strength over a wide range (100 meV) from weak to strong coupling regimes.

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Recent advances in quantum nanophotonics: plexcitonic and vibro-polaritonic strong coupling and its biomedical and chemical applications

et al. 2022

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The fundamental understanding of molecular quantum electrodynamics via the strong light–matter interactions between a nanophotonic cavity and quantum emitters opens various applications in quantum biology, biophysics, and chemistry. However, considerable obstacles to obtaining a clear understanding of coupling mechanisms via reliable experimental quantifications remain to be resolved before this field can truly blossom toward practical applications in quantitative life science and photochemistry. Here, we provide recent advancements of state-of-the-art demonstrations in plexcitonic and vibro-polaritonic strong couplings and their applications. We highlight recent studies on various strong coupling systems for altering chemical reaction landscapes. Then, we discuss reports dedicated to the utilization of strong coupling methods for biomolecular sensing, protein functioning studies, and the generation of hybrid light–matter states inside living cells. The strong coupling regime provides a tool for investigating and altering coherent quantum processes in natural biological processes. We also provide an overview of new findings and future avenues of quantum biology and biochemistry.

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Direct Imaging of Weak‐to‐Strong‐Coupling Dynamics in Biological Plasmon–Exciton Systems

Cited by 3 publications

References 58 publications

Quantum Electrodynamic Behavior of Chlorophyll in a Plasmonic Nanocavity

Quantum Electrodynamic Behavior of Chlorophyll in a Plasmonic Nanocavity

Real‐Time Tuning Exciton‐Plasmon Coupling with Photosensitive Nanocavity

Recent advances in quantum nanophotonics: plexcitonic and vibro-polaritonic strong coupling and its biomedical and chemical applications

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