Data from: Observation of rapid adiabatic passage in optical four-wave mixing
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Abstract
We observe clear evidence of adiabatic passage between photon populations via a four-wave mixing process, implemented through a dispersion sweep arranged by a core diameter taper of an optical fiber. Photonic rapid adiabatic passage through the cubic electric susceptibility thus opens precise control of frequency translation between broadband light fields to all common optical media. Areas of potential impact include optical fiber and on-chip waveguide platforms for quantum information, ultrafast spectroscopy and metrology, and extreme light-matter interaction science.
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Air Force Office of Scientific Research (FA9550-15-1-0356); United States-Israel Binational Science Foundation (BSF) (2014360); Office of Naval Research (N00014-19-1-2592); Dept. of Defense National Defense Science Engineering Graduate Fellowship (NDSEG) Program
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2020-03-30
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Nonlinear Optics; Optical Fiber; Optical Waveguide; Four-Wave Mixing; Quantum Information Processing; Rapid Adiabatic Passage; Optical Frequency Conversion
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Xiaoyue Ding, Dylan Heberle, Kerrianne Harrington, Noah Flemens, Wei-Zung Chang, Tim A. Birks, and Jeffrey Moses, "Observation of rapid adiabatic passage in optical four-wave mixing,” Phys. Rev. Lett. 124, 153902. (2020).
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