# Device Platform for Electrically Reconfigurable Dielectric Metasurfaces

**Authors:** Prasad P Iyer (1), Mihir Pendharkar (1), Chris J. Palmstr{\o}m (1,2), and Jon A. Schuller (1) ((1) Electrical, Computer Engineering Department,, UC Santa Barbara, (2) Science, Engineering Department, UC Santa Barbara)

arXiv: 1903.10280 · 2019-03-26

## TL;DR

This paper presents a novel solid-state device platform for electrically reconfigurable dielectric metasurfaces, enabling independent control of optical antenna elements for dynamic wavefront manipulation.

## Contribution

The work introduces a new heterostructure design and fabrication process for tunable metasurface elements with large phase modulation capabilities.

## Key findings

- Resonant wavelength blue shifts by 200nm during carrier injection.
- Achieves nearly π phase shift in a metasurface array.
- Demonstrates independent electrical control of resonant elements.

## Abstract

Achieving an electrically tunable phased array optical antenna surface has been a principal challenge in the field of metasurfaces. In this letter, we demonstrate a device platform for achieving reconfigurable control over the resonant wavelength of a subwavelength optical antenna through free-carrier injection. We engineer and grow, using molecular beam epitaxy, a heterostructure of In1-xAlxAs/InAs/AlyGa1-ySb layers designed to achieve large amplitude and phase modulation of light by maximizing the refractive index change in regions of resonant field enhancement The p-i-n layers are grown on a heavily doped n-InAs layer which forms a reflecting substrate to confine the Mie resonances within the nanowires of the index tunable layers. We outline the fabrication process developed to form such tunable metasurface elements using a four-step projection lithography process and a self-aligned vertical dry etch. We experimentally demonstrate the operation of an electrically reconfigurable optical antenna element where the resonant wavelength blue shifts by 200nm only during carrier-injection. We extrapolate the experimentally measured InAs refractive index shifts to show we can achieve nearly {\pi} phase shift in a metasurface array. This solid-state device platform enables us to contact each resonant element independently to form a truly reconfigurable Fourier optical element with the promise of arbitrary control of the electromagnetic wavefront at the subwavelength scale.

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Source: https://tomesphere.com/paper/1903.10280