Inverse Design of Integrated Terahertz Vortex Beam Emitters with Staged-Annealing Topology Optimization

TL;DR

This paper introduces a staged-annealing topological optimization framework for designing integrated terahertz vortex beam emitters, demonstrating high efficiency, mode purity, and compactness on an all-silicon platform for advanced photonic applications.

Contribution

The paper presents a novel SATO framework for inverse design of THz photonic devices, enabling efficient, compact, and dual-directional vortex beam emitters with high mode purity.

Findings

Achieved up to 87% mode purity in vortex beams.

Energy conversion efficiency reached 74%.

Devices are ultracompact with footprints less than 4λ.

Abstract

Integrated photonics is increasingly demanded in applications such as large-scale data centers, intelligent sensing, and next-generation wireless communications, where compact, multifunctional, and energy-efficient components are essential. Inverse-designed photonics, empowered by optimization and learning algorithms, have emerged as a powerful paradigm for realizing compact and multifunctional integrated photonic components. In this work, we develop a staged-annealing topological optimization (SATO) framework tailored for the design of integrated terahertz (THz) beam-shaping devices. Employing this inverse-designed framework, we experimentally demonstrate a class of compact THz vortex beam emitters on an all-silicon on-chip platform. These devices efficiently convert the in-plane fundamental transverse electric (TE) waveguide mode into free-space vortex beams with mode purity up to 87% and energy conversion efficiency up to 74% across the target wavelength range (680 {\mu}m to 720 {\mu}m). The inverse-designed emitters exhibit ultracompact footprints (lateral size < 4{\lambda}) and a free-standing configuration, enabling the generation of dual-directional vortex beams carrying opposite topological charges. The proposed SATO framework provides a generalizable and fabrication-compatible approach for THz photonic device engineering, offering a scalable pathway toward complex structured beam manipulation in next-generation wireless communication systems and on-chip integrated THz photonic systems.