纳米技术
陶瓷
计算机科学
3D打印
平版印刷术
表征(材料科学)
材料科学
光学材料
个性化
机械工程
工程类
光电子学
复合材料
万维网
作者
Joel Arriaga‐Dávila,Cristian Rosero‐Arias,Dirk Jonker,Margoth Córdova‐Castro,Josua Zscheile,Robert Kirchner,Alan Aguirre‐Soto,Robert W. Boyd,Israel De Leon,Han Gardeniers,Arturo Susarrey‐Arce
出处
期刊:Small methods
[Wiley]
日期:2025-02-03
卷期号:9 (8): e2401809-e2401809
被引量:11
标识
DOI:10.1002/smtd.202401809
摘要
Feynman's statement, "There is plenty of room at the bottom", underscores vast potential at the atomic scale, envisioning microscopic machines. Today, this vision extends into 3D space, where thousands of atoms and molecules are volumetrically patterned to create light-driven technologies. To fully harness their potential, 3D designs must incorporate high-refractive-index elements with exceptional mechanical and chemical resilience. The frontier, however, lies in creating spatially patterned micro-optical architectures in glass and ceramic materials of dissimilar compositions. This multi-material capability enables novel ways of shaping light, leveraging the interaction between diverse interfaced chemical compositions to push optical boundaries. Specifically, it encompasses both multi-material integration within the same architectures and the use of different materials for distinct architectural features in an optical system. Integrating fluid handling systems with two-photon lithography (TPL) provides a promising approach for rapidly prototyping such complex components. This review examines single and multi-material TPL processes, discussing photoresin customization, essential physico-chemical conditions, and the need for cross-scale characterization to assess optical quality. It reflects on challenges in characterizing multi-scale architectures and outlines advancements in TPL for both single and spatially patterned multi-material structures. The roadmap provides a bridge between research and industry, emphasizing collaboration and contributions to advancing micro-optics.
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