Full-Color Complex-Amplitude Vectorial Holograms Based on Multi-Freedom Metasurfaces

Deng，Zi Lan1; Jin，Mingke2; Ye，Xuan1; Wang，Shuai1; Shi，Tan1; Deng，Junhong2; Mao，Ningbin2; Cao，Yaoyu1; Guan，Bai Ou1; Alù，Andrea3,4,5; Li，Guixin2; Li，Xiangping1

2020

10.1002/adfm.201910610

ADVANCED FUNCTIONAL MATERIALS   影响因子和分区

1616-301X

1616-3028

Phase, polarization, amplitude, and frequency represent the basic dimensions of light, playing crucial roles for both fundamental light–material interactions and all major optical applications. Metasurfaces have emerged as a compact platform to manipulate these knobs, but previous metasurfaces have limited flexibility to simultaneous control them. A multi-freedom metasurface that can simultaneously and independently modulate phase, polarization, and amplitude in an analytical form is introduced, and frequency multiplexing is further realized by a k-space engineering technique. The multi-freedom metasurface seamlessly combines geometric Pancharatnam–Berry phase and detour phase, both of which are frequency independent. As a result, it allows complex-amplitude vectorial hologram at various frequencies based on the same design strategy, without sophisticated nanostructure searching of massive geometric parameters. Based on this principle, full-color complex-amplitude vectorial meta-holograms in the visible are experimentally demonstrated with a metal–insulator–metal architecture, unlocking the long-sought full potential of advanced light field manipulation through ultrathin metasurfaces.

full-color vectorial holograms metasurfaces multi-dimensional manipulation

SCI ; EI

英语

ESI高被引 ; NI期刊 ; ESI高被引 ; ESI高被引

其他

Chemistry ; Science & Technology - Other Topics ; Materials Science ; Physics

Chemistry, Multidisciplinary ; Chemistry, Physical ; Nanoscience & Nanotechnology ; Materials Science, Multidisciplinary ; Physics, Applied ; Physics, Condensed Matter

WOS:000536858100011

WILEY-V C H VERLAG GMBH

20201208318499

Polarization ; Color ; Lithography

Light/Optics:741.1 ; Holography:743

MATERIALS SCIENCE

2-s2.0-85081733145

Scopus

1.Guangdong Provincial Key Laboratory of Optical Fiber Sensing and Communications,Institute of Photonics Technology,Jinan University,Guangzhou,510632,China
2.Department of Materials Science and Engineering,Shenzhen Institute for Quantum Science and Engineering,Southern University of Science and Technology,Shenzhen,518055,China
3.Photonics Initiative,Advanced Science Research Center,City University of New York,New York,85 St. Nicholas Terrace,10031,United States
4.Physics Program,The Graduate Center,City University of New York,New York,365 Fifth Avenue,10016,United States
5.Department of Electrical Engineering,City College of New York,New York,10031,United States

Deng，Zi Lan,Jin，Mingke,Ye，Xuan,et al. Full-Color Complex-Amplitude Vectorial Holograms Based on Multi-Freedom Metasurfaces[J]. ADVANCED FUNCTIONAL MATERIALS,2020,30(21).

Deng，Zi Lan.,Jin，Mingke.,Ye，Xuan.,Wang，Shuai.,Shi，Tan.,...&Li，Xiangping.(2020).Full-Color Complex-Amplitude Vectorial Holograms Based on Multi-Freedom Metasurfaces.ADVANCED FUNCTIONAL MATERIALS,30(21).

Deng，Zi Lan,et al."Full-Color Complex-Amplitude Vectorial Holograms Based on Multi-Freedom Metasurfaces".ADVANCED FUNCTIONAL MATERIALS 30.21(2020).