The ability to design spatial patterns of high carrier density in two-dimensional materials with nanoscale cavity and circuitry features underlies future progress in nonlinear nanophotonics and strong light-matter interactions. Here, we present a general strategy to atomically imprint low-loss graphene plasmonic structures using oxidation-activated charge transfer (OCT). We covered charge-neutral graphene with a monolayer of WSe2, which is subsequently oxidized into a high work-function monolayer WOx to activate charge transfer. Our nano-infrared imaging reveals low-loss plasmon polaritons at the WOx/graphene interface. We insert WSe2 spacers to precisely control the OCT-induced carrier density and to achieve near-intrinsic quality factor of plasmons. Finally, we highlight canonical examples of plasmonic cavities imprinted via programmable OCT, exhibiting laterally abrupt doping profiles with single-digit nanoscale precision. In particular, we demonstrated technologically appealing but elusive plasmonic whispering-gallery resonators based on graphene using OCT-induced free-standing photonic platforms. Our results open avenues for novel quantum photonic architectures incorporating two-dimensional materials.
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Presenters
Brian S Kim
Columbia University
Authors
Brian S Kim
Columbia University
Aaron Sternbach
Columbia University
Min Sup Choi
Columbia University
Zhiyuan Sun
Columbia Univ, Harvard University, Columbia University
Frank L Ruta
Columbia University
Alexander S McLeod
Columbia Univ, Columbia University
Lin Xiong
Columbia Univ
Yinan Dong
Columbia University
Anjaly Rajendran
Columbia University
Song Liu
Columbia University, Columbia University, US, Tim Taylor Department of Chemical Engineering, Kansas State University
Ankur Nipane
Columbia University
Sang Hoon Chae
Columbia University
Xiaodong Xu
University of Washington
Andrew J Millis
Columbia University, Columbia University; Flatiron Institute, Columbia University, Flatiron Institute
