Diatomic Metasurface for Vectorial Holography

Deng, Zi‐Lan; Deng, Junhong; Zhuang, Xin; Wang, Shuai; Li, Kingfai; Wang, Yao; Chi, Yihui; Ye, Xuan; Xu, Jian; Wang, Guo Ping; Zhao, Rongkuo; Wang, Xiaolei; Cao, Yaoyu; Cheng, Xing; Li, Gui Xin; Li, Xiangping

doi:10.1021/acs.nanolett.8b00047

Cited by 289 publications

(226 citation statements)

References 56 publications

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“…Importantly, when the decomposition basis | e + 〉 is chosen as the circular basis | R 〉 = (1, 0) T or (| L 〉 = (0, 1) T ) and the incident beam

| u_{χ, ϑ}, θ_{x}^{n}, θ_{y}^{n} 〉 = e^{j k_{x}^{n} x + j k_{y}^{n} y} (\cos χ | L 〉 + e^{i ϑ} \sin χ | R 〉)

has an arbitrary polarization state, from Equation , one can see that the resultant beam |Ψ ϑ 〉 = cos χ u + | R 〉 + e i ϑ sin χu − | L 〉 exactly describes the spin‐control functionality of the geometric metasurface with additional complex amplitude field control. This means that one can use coherent pixel polarization metaholography to generate arbitrary spatially varying polarization beams, including a full Poincaré beam and vectorial images . Additionally, for the noncircular case of | e + 〉 ≠ | R 〉 or | L 〉, such as in arbitrary spin to orbital conversion and a polarization‐multiplexed display, from Equation , one can see that the polarization pairs of |( e i ) ϑ 〉 or

| {(e_{i}^{*})}_{ϑ} 〉

maintain orthogonality for a linearly polarized incident illumination.…”

Section: Resultsmentioning

confidence: 99%

“…The details of the orthogonality of the polarization pairs of |( e i ) ϑ 〉 or

| {(e_{i}^{*})}_{ϑ} 〉

are given in Note S2 (Supporting Information). Here, the multichannel functionality is readily realized by coherent pixel polarization metaholography based on two pixel types with a fixed resolution, rather than by increasing the number of interleaved meta‐atoms or cells …”

Section: Resultsmentioning

confidence: 99%

“…Interestingly, the spin‐controllable character can be maintained when using the circular polarization basis. It should be noted that such an ultrathin multifunctional metasurface can be fabricated by standard complementary metal‐oxide semiconductor processes, and will enable a broad range of applications, such as optical polarization Möbius strips, polarization‐encrypted data, and quantum experiments, a fiber mode‐multiplexed communication system and arbitrary polarization‐multiplexed print images …”

Section: Resultsmentioning

confidence: 99%

“…Full Poincaré beams have been used to investigate physical systems with exotic nonlinear dynamics . The applications of optical images with spatially varying polarization manipulation include dynamic displays and information encryption . An attempt has also been made to reconstruct a Seifert surface structure by analyzing the polarization ellipse orientations of knotted polarization singularities …”

Section: Introductionmentioning

confidence: 99%

“…Recently, angle‐multiplexed metasurfaces consisting of reflective dielectric U‐shaped meta‐atoms were introduced to encode independent wavefronts at different incident angles. Diatomic metasurfaces consisting of two reflective orthogonal meta‐atoms were proposed for the polarization switching of vectorial holographic images. Continuously polarization‐controlled orbital angular momentum superpositions in multiple channels were reported using a single plasmonic metasurface .…”

Section: Introductionmentioning

confidence: 99%

See 4 more Smart Citations

Complete Control of Multichannel, Angle‐Multiplexed, and Arbitrary Spatially Varying Polarization Fields

Wang

Niu

Liang

et al. 2020

Advanced Optical Materials

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In recent years, much effort is dedicated to the generation of vectorial optical fields with an arbitrary spatially varying polarization distribution by means of metasurfaces. However, simultaneous and independent control of the amplitude, phase, and polarization is still challenging, especially for the multichannel generation of a vectorial optical field with an angle‐multiplexed functionality. Here, a facile route, called coherent pixel polarization metaholography, is proposed to realize multichannel, angle‐multiplexed, and arbitrary spatially varying polarization fields and demonstrate how to enable a fully independent realization of full Poincaré beams (lemon, start, spider, and web beams), dual‐way switching print images, vectorial print images, and optical polarization knot profiles. Importantly, the demonstrated angle‐multiplexed metasurfaces have an independently controllable handedness and azimuth and can possess up to four channels. Such angle‐multiplexed multichannel arbitrary spatial polarization fields may enable various applications, including optical dynamic displays, information communication, optical encryption, and quantum experiments.

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“…Importantly, when the decomposition basis | e + 〉 is chosen as the circular basis | R 〉 = (1, 0) T or (| L 〉 = (0, 1) T ) and the incident beam

| u_{χ, ϑ}, θ_{x}^{n}, θ_{y}^{n} 〉 = e^{j k_{x}^{n} x + j k_{y}^{n} y} (\cos χ | L 〉 + e^{i ϑ} \sin χ | R 〉)

| {(e_{i}^{*})}_{ϑ} 〉

maintain orthogonality for a linearly polarized incident illumination.…”

Section: Resultsmentioning

confidence: 99%

“…The details of the orthogonality of the polarization pairs of |( e i ) ϑ 〉 or

| {(e_{i}^{*})}_{ϑ} 〉

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Complete Control of Multichannel, Angle‐Multiplexed, and Arbitrary Spatially Varying Polarization Fields

Wang

Niu

Liang

et al. 2020

Advanced Optical Materials

View full text Add to dashboard Cite

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Coherent Pixel Design of Metasurfaces for Multidimensional Optical Control of Multiple Printing‐Image Switching and Encoding

Bao

et al. 2018

Adv Funct Materials

116

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Printing image based on metasurface has attracted enormous research interests due to its subwavelength resolution, full‐color printing, and durable properties. Based on the spatially multiplexed pixels, the printing image using metasurface can be switched optically by altering the optical parameters, such as polarization and incident wavelength. However, such multiplexed pixel design has several problems, including the cross‐talk among different wavelengths, limitation to linear polarizations, and incapability for incident‐angle control. Here, a general method for pixel design, called the coherent pixel, which can overcome the problems and be used for multiple printing‐image switching controlled by arbitrary optical parameters (arbitrary incident angle, polarization, and wavelength) is proposed. Based on this coherent pixel, metasurface devices with novel functionalities can be realized, such as incident‐angle controlled and arbitrary polarization‐controlled printing images, which are not feasible with previous conventional pixel design method. The suitability and superiority of the coherent pixel for encryption application is also discussed. Such printing‐image switching controlled with arbitrary optical parameters should pave the way for various applications, including various functional switchable optical devices, image displays, and information encryption.

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

Deng

Jin

et al. 2020

Adv Funct Materials

Self Cite

233

167

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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 complexamplitude vectorial meta-holograms in the visible are experimentally demonstrated with a metal-insulator-metal architecture, unlocking the longsought full potential of advanced light field manipulation through ultrathin metasurfaces.functional layers, emerge as a desirable platform to manipulate the light field at will with large control and flexibility. [3][4][5][6][7] Exciting applications have already been demonstrated on the metasurface platform, including flat diffractive and polarization optical components, much more compact and lightweight than conventional bulky counterparts. By engineering the scattering properties of the individual metaelements constituting the metasurface to mold the geometric phase, resonant phase or propagation phase, we are able to control phase, [8,9] amplitude, [10,11] polarization, [12,13] or frequency [14][15][16] of light, leading to high-efficiency metalenses, [9] high-fidelity holograms, [8] broadband polarization components, [12,17] and highperformance biosensors. [15] However, these ultrathin components tend to focus on single-dimensional light manipulation, controlling either the local phase, or amplitude, or polarization, or frequency, at a time, inherently limiting potential opportunities. For example, metasurface holograms and metalenses based on resonant phase and propagation phase are typically limited to a narrow range of frequencies. [18,19] Geometric Pancharatnam-Berry (P-B) phase metasurfaces operate over broader bandwidths, but they are restricted to circular polarization only. [8] To improve the performance and enrich the functionality of metasurfaces for a broader range of applications, independent

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Diatomic Metasurface for Vectorial Holography

Cited by 289 publications

References 56 publications

Complete Control of Multichannel, Angle‐Multiplexed, and Arbitrary Spatially Varying Polarization Fields

Complete Control of Multichannel, Angle‐Multiplexed, and Arbitrary Spatially Varying Polarization Fields

Coherent Pixel Design of Metasurfaces for Multidimensional Optical Control of Multiple Printing‐Image Switching and Encoding

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

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