Nonreciprocal Wavefront Engineering with Time-Modulated Gradient Metasurfaces

Zang, Jiawei; Correas-Serrano, D.; Do, James; Liu, X.; Álvarez‐Melcón, A.; Gómez‐Díaz, J. S.

doi:10.1103/physrevapplied.11.054054

Cited by 113 publications

(98 citation statements)

References 64 publications

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“…Dynamic modulation of a metasurface provides the required momentum for the transition of fundamental frequency to higher‐order frequency harmonics defined as f n = f 0 + nf m with the integer

n \in ℤ

denoting the order of generated frequency harmonics . As such, unlike static and quasi‐static metasurfaces which can only change the spatial features of scattered light, dynamically modulated metasurfaces provide control over the spectral content of the scattered light as well.…”

Section: Time‐modulated Metasurfacementioning

confidence: 99%

“…It has been recently shown that the imprinted phase gradient on the wavefront of higher‐order frequency harmonics generated by a time‐modulated metasurface can be controlled by tuning the modulation phase delay of the elements . Specifically, by introducing a modulation phase delay of α, the n th frequency harmonic acquires a phase shift of nα while maintaining a constant amplitude .…”

Section: Applicationsmentioning

confidence: 99%

“…A high‐speed continuous tuning mechanism for all‐dielectric metasurfaces not only allows for real‐time control over the optical response but also enables realization of time‐modulated metasurfaces by applying time‐varying external stimuli. Despite their linearity, time‐modulated metasurfaces exhibit frequency‐mixing property and lead to generation of higher‐order frequency harmonics which are consisted of fundamental frequency up‐ and down‐modulated by the frequency of biasing . Unlike frequency conversion in nonlinear metasurfaces which requires high optical intensities and operates for one excitation at a time, frequency conversion in time‐modulated metasurfaces can be achieved for simultaneous excitations with arbitrary intensities.…”

Section: Introductionmentioning

confidence: 99%

“…Time modulation also renders a 4D design space and provides new degrees of freedom in light manipulation which can be used to overcome several limitations associated with quasi‐static tunable metasurfaces. In particular, the light acquires a dispersionless phase shift upon undergoing frequency conversion in a time‐modulated metasurfaces which is linearly proportional to the harmonic order and modulation phase delay, while maintaining a constant amplitude . This creates a new paradigm for designing dynamic metasurfaces with 2π phase span and uniform amplitude.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

A Dynamically Modulated All‐Dielectric Metasurface Doublet for Directional Harmonic Generation and Manipulation in Transmission

Salary

Farazi

Mosallaei

2019

Advanced Optical Materials

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metasurface to achieve a certain functionality in reflection or transmission mode. Recent years have witnessed the development of phase-gradient metasurfaces with different configurations for a wide range of applications such as beam-steering, focusing, and holography. [1,2] These structures allow for integration of various functionalities into a flat surface thus leading to a dramatic reduction in the footprint of optical systems by replacing conventional bulky optical components.Spatiotemporal control over the phase of transmitted and reflected lights across the 2π span is the key to achieve the desired functionalities. The phase tuning mechanisms of metasurfaces have been mostly based on varying the size of nanoantennas within the resonant scattering regime or rotating half-wave plate elements to imprint a geometric phase shift on the circularly polarized light scattered with the opposite handedness. [3,4] For a nanoantenna supporting a single isolated electric or magnetic resonance, the maximal resonant phase agility is π which hinders full control over the light wavefront without employing a back mirror. Metasurfaces with both electric and magnetic responses can be used to overcome this limitation via spectrally overlapping [5] and interleaving [6] electric and magnetic resonances for operation in transmission and reflection modes, respectively. The spectral overlap of electric and magnetic dipole resonances in a Huygens' metasurface satisfies the first Kerker condition leading to suppressed backward scattering from the elements thus eliminating the reflection and giving rise to maximal transmission with 2π phase agility. Although Huygens' metasurfaces have been constructed using metallic elements in microwave regime, bringing plasmonic Huygens' metasurfaces into optical frequencies is challenging due to their complex geometries and arrangements, and is further hindered by the significant increase in the ohmic loss of plasmonic materials at higher frequencies. [7] All-dielectric metasurfaces consisted of high-index subwavelength elements embedded in a low-index environment can eliminate these limitations in that they can support both electric and magnetic resonances with simple geometries and do not suffer from significant dissipative losses. [8][9][10] Moreover, they are fully compatible with standard In this paper, an electrically tunable all-dielectric metasurface doublet is proposed operating at mid-infrared frequency regime with dynamic 2π phase span in transmission mode. Each layer of the metasurface consists of a periodic array of silicon nanobars configured into p-i-n junctions in which the double carrier injection into the intrinsic region under forward bias allows for tuning of the silicon refractive index. The physical mechanism is based on the spectral overlap of high quality factor guided mode resonances supported by each constituent layer establishing an extreme Huygens' operation regime of nearly reflectionless transmission with steep phase spectrum. The short response time of field-driven car...

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“…Dynamic modulation of a metasurface provides the required momentum for the transition of fundamental frequency to higher‐order frequency harmonics defined as f n = f 0 + nf m with the integer

n \in ℤ

Section: Time‐modulated Metasurfacementioning

confidence: 99%

Section: Applicationsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

A Dynamically Modulated All‐Dielectric Metasurface Doublet for Directional Harmonic Generation and Manipulation in Transmission

Salary

Farazi

Mosallaei

2019

Advanced Optical Materials

View full text Add to dashboard Cite

show abstract

“…However, a fully tailored electromagnetic response requires metasurfaces that can continuously alter their scattering properties simultaneously in time and space. These functionalities can be achieved in spatio-temporally modulated metasurfaces 31 (STMMs), which have the potential to revolutionize fundamental and applied photonics, including nonreciprocity 32,33 , through on-demand control of frequency and momentum harmonic contents of scattered light. For example, an STMM can focus a collimated beam ( Fig.…”

mentioning

confidence: 99%

Surface-wave-assisted nonreciprocity in spatio-temporally modulated metasurfaces

et al. 2020

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Corresponding authors: A.A.: aazad@lanl.gov and D.D.: dalvit@lanl.gov 2 Emerging photonic functionalities are mostly governed by the fundamental principle of Lorentz reciprocity. Lifting the constraints imposed by this principle could circumvent deleterious effects that limit the performance of photonic systems. A variety of approaches have recently been explored to break reciprocity, yet most efforts have been limited to confined photonic systems. Here, we propose and experimentally demonstrate a spatiotemporally modulated metasurface capable of extreme breakdown of Lorentz reciprocity. Through tailoring the momentum and frequency harmonic contents of the scattered waves, we achieve dynamical beam steering, reconfigurable focusing, and giant free-space optical isolation exemplifying the flexibility of our platform. We develop a generalized Bloch-Floquet theory which offers physical insights into the demonstrated extreme nonreciprocity, and its predictions are in excellent agreement with experiments. Our work opens exciting opportunities in applications where free-space nonreciprocal wave propagation is desired, including wireless communications and radiative energy transfer.

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