Electro-Optic Modulation in Polycrystalline Barium Titanate Metasurfaces Enhanced by Poling

TL;DR

This paper demonstrates scalable, high-Q polycrystalline barium titanate metasurfaces with enhanced electro-optic modulation through poling and domain alignment, enabling efficient, tunable free-space optical devices at low voltages.

Contribution

It introduces a scalable fabrication approach for BTO metasurfaces with improved EO modulation via ferroelectric domain engineering, surpassing previous performance benchmarks.

Findings

High quality factor resonances up to 200 achieved.

Modulation strength increased by up to 25% with domain alignment.

Operates at sub-volt voltages and frequencies up to 5 MHz.

Abstract

Electrically tunable metasurfaces leveraging the strong Pockel's effect in barium titanate (BaTiO$_3$ or BTO) are a promising platform for reconfigurable free-space optical devices. However, the high cost, limited scalability, and restricted substrate compatibility of epitaxial BTO films hinder its exploitation. Here, we demonstrate free-space optical modulators based on imprinted BTO metasurfaces with targeted designs for optical and electric field confinement within the active material. With resonances exhibiting high quality factors of up to 200, we demonstrate improved transmission modulation at sub-volt driving amplitudes and frequencies up to 5 MHz. Additional enhancement is achieved via ferroelectric domain alignment, resulting in up to 25 % higher modulation strength compared to the unbiased case and up to 75 % compared to previous demonstrations. This enhanced EO response, arising from the effective permittivity engineering and domain orientation in these polycrystalline metasurfaces, holds significant potential for scalable and efficient EO modulators and active metasurfaces.