1. Optical valley Hall effect for highly valley-coherent exciton-polaritons in an atomically thin semiconductor
- Author
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Nils Lundt, Evgeny Sedov, Ying Qin, Martin Klaas, Johannes Beierlein, Ł. Dusanowski, Maxime Richard, Alexey Kavokin, Mikhail M. Glazov, Sebastian Klembt, Christian Schneider, Sven Höfling, Sefaattin Tongay, Petr Stepanov, University of St Andrews. Condensed Matter Physics, University of St Andrews. School of Physics and Astronomy, University of Würzburg = Universität Würzburg, Stoletov’s Vladimir State University (VSU), Nanophysique et Semiconducteurs (NPSC), Institut Néel (NEEL), Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes [2016-2019] (UGA [2016-2019])-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes [2016-2019] (UGA [2016-2019]), A.F. Ioffe Physical-Technical Institute, Russian Academy of Sciences [Moscow] (RAS), Arizona State University [Tempe] (ASU), Westlake University [Zhejiang], Technische Physik, and Julius-Maximilians-Universität Würzburg [Wurtzbourg, Allemagne] (JMU)
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Photon ,[PHYS.COND.GAS]Physics [physics]/Condensed Matter [cond-mat]/Quantum Gases [cond-mat.quant-gas] ,Exciton ,Biomedical Engineering ,NDAS ,Physics::Optics ,FOS: Physical sciences ,Bioengineering ,02 engineering and technology ,Exciton-polaritons ,010402 general chemistry ,01 natural sciences ,7. Clean energy ,Photonic metamaterial ,[PHYS.QPHY]Physics [physics]/Quantum Physics [quant-ph] ,Hall effect ,Mesoscale and Nanoscale Physics (cond-mat.mes-hall) ,Polariton ,General Materials Science ,Electrical and Electronic Engineering ,ComputingMilieux_MISCELLANEOUS ,QC ,Physics ,Condensed matter physics ,Condensed Matter - Mesoscale and Nanoscale Physics ,business.industry ,021001 nanoscience & nanotechnology ,Condensed Matter Physics ,Condensed Matter::Mesoscopic Systems and Quantum Hall Effect ,Atomic and Molecular Physics, and Optics ,0104 chemical sciences ,Semiconductor ,QC Physics ,Quantum Gases (cond-mat.quant-gas) ,Photonics ,0210 nano-technology ,business ,Condensed Matter - Quantum Gases - Abstract
C.S. acknowledges support by the ERC (Project unLiMIt-2D). The Würzburg group acknowledges support by the State of Bavaria. A.V.K. acknowledges the support from Westlake University (Project No. 041020100118). E.S. acknowledges support from the President of the Russian Federation for state support of young Russian scientists Grant No. MK-2839.2019.2 and the RFBR Grant No. 17-52-10006. S.K. acknowledges support by the EU (Marie Curie Project TOPOPOLIS). Q.Y. and S.T. acknowledge funding from NSF DMR-1838443 and DMR-1552220. M.M.G. acknowledges partial support from RFBR Project 17-02-00383. Spin–orbit coupling is a fundamental mechanism that connects the spin of a charge carrier with its momentum. In the optical domain, an analogous synthetic spin–orbit coupling is accessible by engineering optical anisotropies in photonic materials. Both yield the possibility of creating devices that directly harness spin and polarization as information carriers. Atomically thin transition metal dichalcogenides promise intrinsic spin-valley Hall features for free carriers, excitons and photons. Here we demonstrate spin- and valley-selective propagation of exciton-polaritons in a monolayer of MoSe2 that is strongly coupled to a microcavity photon mode. In a wire-like device we trace the flow and helicity of exciton-polaritons expanding along its channel. By exciting a coherent superposition of K and K′ tagged polaritons, we observe valley-selective expansion of the polariton cloud without either an external magnetic field or coherent Rayleigh scattering. The observed optical valley Hall effect occurs on a macroscopic scale, offering the potential for applications in spin-valley-locked photonic devices. Postprint Postprint
- Published
- 2019
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