T
Tomoyuki Yoshie
Researcher at Duke University
Publications - 74
Citations - 3738
Tomoyuki Yoshie is an academic researcher from Duke University. The author has contributed to research in topics: Photonic crystal & Photonics. The author has an hindex of 17, co-authored 74 publications receiving 3543 citations. Previous affiliations of Tomoyuki Yoshie include California Institute of Technology & Kyoto University.
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Journal ArticleDOI
Vacuum Rabi splitting with a single quantum dot in a photonic crystal nanocavity
Tomoyuki Yoshie,Axel Scherer,Joshua R. Hendrickson,Galina Khitrova,H. M. Gibbs,G. Rupper,Claudia Ell,Oleg B. Shchekin,Dennis G. Deppe +8 more
TL;DR: The experimental realization of a strongly coupled system in the solid state is reported: a single quantum dot embedded in the spacer of a nanocavity, showing vacuum-field Rabi splitting exceeding the decoherence linewidths of both the nanoc Cavity and the quantum dot.
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Low-Threshold Photonic Crystal Laser
TL;DR: In this article, a photonic crystal nanocavity laser was fabricated based on a high-quality factor design that incorporates fractional edge dislocations, and the laser was optically pumped with 10 ns pulses, and lased at threshold pumping powers below 220 μW.
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Scanning a photonic crystal slab nanocavity by condensation of xenon
S. Mosor,Joshua R. Hendrickson,B. C. Richards,Julian Sweet,Galina Khitrova,H. M. Gibbs,Tomoyuki Yoshie,Axel Scherer,Oleg B. Shchekin,Dennis G. Deppe +9 more
TL;DR: In this article, a photonic crystal slab nanocavity was used to change the detuning between a single quantum dot transition and the cavity mode for cavity quantum electrodynamics experiments, such as mapping out a strong coupling anticrossing curve.
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High Quality Two-Dimensional Photonic Crystal Slab Cavities
TL;DR: In this article, a donor-mode nanocavity was constructed by a single defect cavity defined within a two-dimensional photonic crystal slab, where quantum dots emitting in the 1.1-1.3 micron range were used as luminescence sources.
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Optical microcavity: sensing down to single molecules and atoms.
TL;DR: Qualitative optics effects based on microcavity quantum electrodynamics (QED) would provide novel single-photo-level detection of even single atoms and molecules via detection of doublet vacuum Rabi splitting peaks in strong coupling.