Machine learning to optimize additive manufacturing for visible photonics

Andrew Lininger; Akeshi Aththanayake; Jonathan Boyd; Omar Ali; Madhav Goel; Yangheng Jizhe; Michael Hinczewski; Giuseppe Strangi

doi:10.1515/nanoph-2022-0815

Machine learning to optimize additive manufacturing for visible photonics

Nanophotonics. 2023 Mar 17;12(14):2767-2778. doi: 10.1515/nanoph-2022-0815. eCollection 2023 Jul.

Authors

Andrew Lininger¹, Akeshi Aththanayake¹, Jonathan Boyd¹, Omar Ali¹, Madhav Goel¹, Yangheng Jizhe¹, Michael Hinczewski¹, Giuseppe Strangi^{1

2}

Affiliations

¹ Department of Physics, Case Western Reserve University, 2076 Adelbert Rd., Cleveland, OH 44106, USA.
² University of Calabria and CNR - Institute of Nanotechnology, Rende, CS, Italy.

Abstract

Additive manufacturing has become an important tool for fabricating advanced systems and devices for visible nanophotonics. However, the lack of simulation and optimization methods taking into account the essential physics of the optimization process leads to barriers for greater adoption. This issue can often result in sub-optimal optical responses in fabricated devices on both local and global scales. We propose that physics-informed design and optimization methods, and in particular physics-informed machine learning, are particularly well-suited to overcome these challenges by incorporating known physics, constraints, and fabrication knowledge directly into the design framework.

Keywords: additive manufacturing; machine learning; nanophotonics; physics-informed machine learning; two-photon polymerization.