Macroscopic Structural Light Absorbers

TL;DR

This paper introduces macroscopic structural light absorbers made from minimal surface approximations and stochastic lattices, reducing stray light effectively without complex coatings, suitable for aerospace and industrial applications.

Contribution

It presents a novel design of macroscopic light absorbers using minimal surface structures, demonstrating effective stray light reduction through geometric configurations rather than coatings.

Findings

Peak intensity reduced by factors less than 0.39

Average intensity reduced by factors less than 0.65

Supports cost-effective, robust materials like anodised aluminium

Abstract

The interaction of light with optical and mechanical systems is influenced by material properties, geometrical configurations, and surface topographies. Designing these systems necessitates a careful balance of conflicting requirements, such as minimising size and weight while simultaneously improving heat transfer and reducing stray light from illuminated peripheral mounting surfaces. Stray light is typically mitigated by apertures, coatings, and microscopic structures, alongside maintaining cleanliness. However, using apertures may not always be feasible, and effective optical absorber coatings or microscopic light absorbing structures can be costly and sensitive to environmental factors such as abrasion, radiation heating, or cleaning agents. In a proof-of-concept investigation, we design and analyse macroscopic structural light absorbers realised as periodic minimal surface approximations and quasi-stochastic lattices. The term "macroscopic" refers to minimal structural dimensions of approximately 100 micrometres. By increasing the number of reflections before residual reflected light reaches a hemispherical receiver, we achieve reductions in received peak intensities by factors of less than 0.39 and average intensities by factors of less than 0.65, without altering the surface properties. Macroscopic structural light absorbers support cost-effective and robust light-absorbing materials, such as black anodised aluminium or ABS polymers, while still achieving satisfactory stray light suppression. This approach is applicable to aerospace optical systems (such as telescopes and imaging spectrometers), as well as general scientific and industrial optical instruments and commercial products (including projectors and luminaires). The demonstrated structures can be sustainably fabricated through additive manufacturing processes like laser powder bed fusion.