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Reversible Three‐Dimensional Focusing of Visible Light with Ultrathin Plasmonic Flat Lens
Author(s) -
Chen Xianzhong,
Huang Lingling,
Mühlenbernd Holger,
Li Guixin,
Bai Benfeng,
Tan Qiaofeng,
Jin Guofan,
Qiu ChengWei,
Zentgraf Thomas,
Zhang Shuang
Publication year - 2013
Publication title -
advanced optical materials
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.89
H-Index - 91
ISSN - 2195-1071
DOI - 10.1002/adom.201300102
Subject(s) - optics , lens (geology) , classification of discontinuities , materials science , plasmon , virtual image , plasmonic lens , plane (geometry) , phase (matter) , ray , optoelectronics , physics , surface plasmon , surface plasmon polariton , geometry , mathematical analysis , mathematics , quantum mechanics
Metasurfaces with interfacial phase discontinuities provide a unique platform for manipulating light propagation both in free space and along a surface. Three‐dimensional focusing of visible light is experimentally exhibited as a bi‐functional phenomenon by controlling the radial orientation of identical plasmonic dipoles, generating a desired phase profile along the interface. With this technique, the in‐plane and out‐of‐plane refractions are manipulated by an ultrathin flat lens such that a beam can be focused into a 3D spot either in a real or virtual focal plane, which can be reversed via manipulation of the circularly polarized status of the incident light. Both the inverted real image and the upright virtual image of an arbitrary object are experimentally demonstrated using the same flat lens in the visible range, which paves the way towards robust application of phase discontinuity devices.