Nanoscale quantum optics
Year: 2019
Authors: D’Amico I., Angelakis D. G., Bussières F., Caglayan H., Couteau C., DurtT., Kolaric B., Maletinsky P., Pfeiffer W., Rabl P., Xuereb A., Agio M.
Autors Affiliation: Univ York, Dept Phys, York, N Yorkshire, England; Univ Fed Rio Grande do Norte, Int Inst Phys, Natal, RN, Brazil; Tech Univ Crete, Sch Elect & Comp Engn, Khania, Greece; Natl Univ Singapore, Ctr Quantum Technol, Singapore, Singapore; Univ Geneva, GAP Quantum Technol, Geneva, Switzerland; ID Quant SA, Carouge, Switzerland; Tampere Univ, Fac Engn & Nat Sci, Photon, Tampere, Finland; Univ Technol Troyes, L2n, Troyes, France; Aix Marseille Univ, Inst Fresnel, CNRS, Cent Marseille, Marseille, France; Univ Mons, Micro & Nanophoton Mat Grp, Mons, Belgium; Univ Belgrade, Inst Phys, Photon Ctr, Belgrade, Serbia; Old World Labs, Virginia Beach, VA USA; Univ Basel, Dept Phys, Basel, Switzerland; Univ Bielefeld, Fac Phys, Bielefeld, Germany; TU Wien, Atominst, Vienna, Austria; Univ Malta, Dept Phys, Msida, Malta; Univ Siegen, Lab Nanoopt & C, Siegen, Germany; CNR, Natl Res Council, Natl Inst Opt, INO, Florence, Italy.
Abstract: Nanoscale quantum optics explores quantum phenomena in nanophotonics systems for advancing fundamental knowledge in nano and quantum optics and for harnessing the laws of quantum physics in the development of new photonics-based technologies. Here, we review recent progress in the field with emphasis on four main research areas: Generation, detection, manipulation and storage of quantum states of light at the nanoscale, nonlinearities and ultrafast processes in nanostructured media, nanoscale quantum coherence, cooperative effects, correlations and many-body physics tailored by strongly confined optical fields. The focus is both on basic developments and technological implications, especially concerning information and communication technology, sensing and metrology, and energy efficiency.
Journal/Review: RIVISTA DEL NUOVO CIMENTO
Volume: 42 (4) Pages from: 153 to: 195
More Information: This article is based upon work from COST Action MP1403 “Nanoscale Quantum Optics,” supported by COST (European Cooperation in Science and Technology). The authors would like to acknowledge input from D. Chang, V. Giesz, S. Kuck, R. Oulton, and C. Sibilia. T. Durt and B. Kolaric acknowledge the help of Mrs. B. Bokic, Institute of Physics, University of Belgrade in editing images for the section Nanoscale Quantum Coherence. A. Xuereb acknowledges funding by the European Union´s Horizon 2020 research and innovation programme under grant agreement No 732894 (FET Proactive HOT) and wishes to thank G. Di Giuseppe, N. Kralj, E. Serra, and D. Vitali for providing fig. 16c.KeyWords: single-photon sources; energy-transfer; spectroscopic signatures; plasmonic nanostructures; phase-transition; room-temperature; charge-transfer; real-time; light; generation; quantum optics; nano-opticsDOI: 10.1393/ncr/i2019-10158-0ImpactFactor: 6.875Citations: 15data from “WEB OF SCIENCE” (of Thomson Reuters) are update at: 2024-09-15References taken from IsiWeb of Knowledge: (subscribers only)Connecting to view paper tab on IsiWeb: Click hereConnecting to view citations from IsiWeb: Click here
