Topology-optimized distributed 3d anisotropic Raman emission
Abstract
Topology optimization (TO) of 3D surface-enhanced Raman scattering (SERS) substrates faces challenges in managing field singularities and modeling orientation-averaged anisotropic molecules. We present 3D TO for manufacturable SERS substrates that maximize spatially averaged signals from randomly oriented, anisotropic molecules in both elastic and inelastic scattering. A new trace formulation provides a closed-form rotational average of anisotropic Raman tensors, which are not equivalent to isotropic molecules because of tensor nonlinearity. Optimized silver and Si3N4 devices show that lengthscale constraints are sufficient to suppress designs that rely on unphysical mathematical field divergences at sharp corners. Metallic designs deliver broadband enhancement and remain robust to typical Raman shifts, whereas dielectric designs yield narrower, quality-factor-limited gains that are inferior to metallic designs for quality factors below about 500. Our approach readily incorporates additional physics, such as a nonlinear damage model. Together, these results provide a practical route to improved manufacturable SERS substrates and extend naturally to other distributed-emitter design problems.
Cite
@article{arxiv.2602.00339,
title = {Topology-optimized distributed 3d anisotropic Raman emission},
author = {Ian M. Hammond and Pengning Chao and Henry O. Everitt and Rasmus E. Christiansen and Alan Edelman and Francesc Verdugo and Steven G. Johnson},
journal= {arXiv preprint arXiv:2602.00339},
year = {2026}
}
Comments
18 pages, 5 figures