Counting All Photons: Efficient Optimization of Visible Light 3D Printing

The utility of visible light for 3D printing has increased in recent years owing to its accessibility and reduced materials interactions, such as scattering and absorption/degradation, relative to traditional UV light-based processes. However, photosystems that react efficiently with visible light often require multiple molecular components and have strong and diverse absorption profiles, increasing the complexity of formulation and printing optimization. Herein, a streamlined method to select and optimize visible light 3D printing conditions is described. First, green light liquid crystal display (LCD) 3D printing using a novel resin is optimized through traditional empirical methods, which involves resin component selection, spectroscopic characterization, time-intensive 3D printing under several different conditions, and measurements of dimensional accuracy for each printed object. Subsequent analytical quantification of dynamic photon absorption during green light polymerizations unveils relationships to cure depth that enables facile resin and 3D printing optimization using a model that is a modification to the Jacob's equation traditionally used for stereolithographic 3D printing. The approach and model are then validated using a distinct green light-activated resin for two types of projection-based 3D printing.

Automated summary

The use of visible light for 3D printing has increased due to its accessibility and reduced materials interactions compared to UV light-based processes. However, efficient photosystems for visible light often require multiple molecular components and have diverse absorption profiles, making formulation and printing optimization more complex. This study presents a streamlined method for selecting and optimizing visible light 3D printing conditions.