Dual-Gated Active Metasurface at 1550 nm with Wide (&gt;300°) Phase Tunability

Shirmanesh, Ghazaleh Kafaie; Sokhoyan, Ruzan; Pala, Ragıp; Atwater, Harry A.

doi:10.1021/acs.nanolett.8b00351

Cited by 212 publications

(266 citation statements)

References 42 publications

(95 reference statements)

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“…While these are static optical components, for which the phase coverage can be achieved via arranging the constituent nanoantennas with different shapes, sizes, or orientations, for various applications it is also important to find ways to adaptively tune the phase brought to light by the nanoantennas during usage. [25][26][27][28][29][30][31][32][33][34][35] Ultimately, if each single nanoantenna element of a metasurface could be dynamically tuned by applying electrical voltages then it would act as an SLM device with a pixel size smaller than the wavelength of light.…”

Section: Introductionmentioning

confidence: 99%

Phase-only transmissive spatial light modulator based on tunable dielectric metasurface

Veetil

et al. 2019

Science

469

371

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Rapidly developing augmented reality (AR) and 3D holographic display technologies require spatial light modulators (SLM) with high resolution and viewing angle to be able to satisfy increasing customer demands. Currently available SLMs, as well as their performance, are limited by their large pixel sizes of the order of several micrometres. Further pixel size miniaturization has been stagnant due to the persistent challenge to reduce the inter-pixel crosstalk associated with the liquid crystal (LC) cell thickness, which has to be large enough to accumulate the required 2π phase difference. Here, we propose a concept of tunable dielectric metasurfaces modulated by a liquid crystal environment, which can provide abrupt phase change and uncouple the phase accumulation from the LC cell thickness, ultimately enabling the pixel size miniaturization. We present a proof-of-concept metasurface-based SLM device, configured to generate active beam steering with >35% efficiency and large beam 2 deflection angle of 11°, with LC cell thickness of only 1.5 μm, much smaller than conventional devices. We achieve the pixel size of 1.14 μm corresponding to the image resolution of 877 lp/mm, which is 30 times larger comparing to the presently available commercial SLM devices.High resolution and viewing angle of the metasurface-based SLMs opens up a new path to the next generation of near-eye AR and 3D holographic display technologies.

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Section: Introductionmentioning

confidence: 99%

Phase-only transmissive spatial light modulator based on tunable dielectric metasurface

Veetil

et al. 2019

Science

469

371

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“…Furthermore, unlike all-optical tunability, electrical tunability easily allows for realization of gradedpatterns through independent biasing of each element without requiring complex lens systems which makes it desirable for wavefront engineering. In particular, graphene and indium tin oxide (ITO) have attracted a lot of attention due to their compatibility with silicon technology, large scale fabrication feasibility and lowdimensionality of the active regions [19,20,24,25]. The carrier concentration in these materials can be tuned through electrostatic gating in parallel capacitor configurations which can be translated into the change in the optical constants of the material through carrier-dependent dispersion models in the infrared (IR) and Terahertz (THz) frequencies.…”

Section: Introductionmentioning

confidence: 99%

Electrically tunable harmonics in time-modulated metasurfaces for wavefront engineering

2018

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Modulation of metasurfaces in time gives rise to several exotic space-time scattering phenomena by breaking the reciprocity constraint and generation of higher-order frequency harmonics. We introduce a new design paradigm for time-modulated metasurfaces, enabling tunable engineering of the generated frequency harmonics and their emerging wavefronts by electrically controlling the phase delay in modulation. It is demonstrated that the light acquires a dispersionless phase shift regardless of incident angle and polarization, upon undergoing frequency conversion in a timemodulated metasurface which is linearly proportional to the modulation phase delay and the order of generated frequency harmonic. The conversion efficiency to the frequency harmonics is independent of modulation phase delay and only depends on the modulation depth and resonant characteristics of the metasurface, with the highest efficiency occurring in the vicinity of resonance, and decreasing away from the resonant regime. The modulation-induced phase shift allows for creating tunable spatially varying phase discontinuities with 2π span in the wavefronts of generated frequency harmonics for a wide range of frequencies and incident angles. Specifically, we apply this approach to a time-modulated metasurface in the Teraherz regime consisted of graphene-wrapped silicon microwires. For this purpose, we use an accurate and efficient semi-analytical framework based on multipole scattering. We demonstrate the utility of the design rule for tunable beam steering and focusing of generated frequency harmonics giving rise to several intriguing effects such as spatial decomposition of harmonics, anomalous bending with full coverage of angles and dual-polarity lensing. Furthermore, we investigate the angular and spectral performance of the time-modulated metasurface in manipulation of generated frequency harmonics to verify its constant phase response versus incident wavelength and angle. The nonreciprocal response of the metasurface in wavefront engineering is also studied by establishing nonreciprocal links with large isolations via modulationinduced phase shift. The proposed design approach enables a new class of high-efficiency tunable metasurfaces with wide angular and frequency bandwidth, wavefront engineering capabilities, nonreciprocal response and multi-functionality.

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“…The slight increase in integrated heat flux at point A, with respect to bulk SiC, in Fig. 4c, results from the large plasmonic losses (γ p ) in ITO, namely γ ITO = [200 − 263]γ SiC [41,58,59,61,62,66], for the range of carrier densities considered here. The ITO losses result in a slightlybroadened SPhP peak in spectral heat flux (dashed curve in panel (d)) with respect to bulk SiC (black curve in panel (d)), which, when integrated, results in a Q larger than Q SiC .…”

Section: A Transparent Conductive Oxidesmentioning

confidence: 89%

“…In the class of TCOs we investigate ITO, which is traditionally used as a contact electrode in photovoltaic cells due to its simultaneous conducting and transparent nature. ITO is an emerging plasmonic material with considerably lower losses compared to noble metals, while also having gate-tunable carrier density [58,59,[61][62][63][64][65].…”

Section: Practical Implementationmentioning

confidence: 99%

Gate-Tunable Near-Field Heat Transfer

et al. 2019

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Active control over the flow of heat in the near-field holds promise for nanoscale thermal management, with applications in refrigeration, thermophotovoltaics, and thermal circuitry. Analogously to its electronic counterpart, the metal-oxide-semiconductor (MOS) capacitor, we propose a thermal switching mechanism based on accumulation and depletion of charge carriers in an ultra-thin plasmonic film, via application of external bias. In our proposed configuration, the plasmonic film is placed on top of a polaritonic dielectric material that provides a surface phonon polariton (SPhP) thermal channel, while also ensuring electrical insulation for application of large electric fields. The variation of carrier density in the plasmonic film enables the control of the surface plasmon polariton (SPP) thermal channel. We show that the interaction of the SPP with the SPhP significantly enhances the net heat transfer. We study SiC as the oxide and explore three classes of gate-tunable plasmonic materials: transparent conductive oxides, doped semiconductors, and graphene, and theoretically predict contrast ratios as high as 225%.

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Dual-Gated Active Metasurface at 1550 nm with Wide (>300°) Phase Tunability

Cited by 212 publications

References 42 publications

Phase-only transmissive spatial light modulator based on tunable dielectric metasurface

Phase-only transmissive spatial light modulator based on tunable dielectric metasurface

Electrically tunable harmonics in time-modulated metasurfaces for wavefront engineering

Gate-Tunable Near-Field Heat Transfer

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