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Additive Manufacturing: Applications and Directions in Photonics and Optoelectronics
Advanced Optical Materials ( IF 8.0 ) Pub Date : 2018-09-16 , DOI: 10.1002/adom.201800419
Andrea Camposeo 1 , Luana Persano 1 , Maria Farsari 2 , Dario Pisignano 1, 3
Affiliation  

The combination of materials with targeted optical properties and of complex, 3D architectures, which can be nowadays obtained by additive manufacturing, opens unprecedented opportunities for developing new integrated systems in photonics and optoelectronics. The recent progress in additive technologies for processing optical materials is here presented, with emphasis on accessible geometries, achievable spatial resolution, and requirements for printable optical materials. Relevant examples of photonic and optoelectronic devices fabricated by 3D printing are shown, which include light‐emitting diodes, lasers, waveguides, optical sensors, photonic crystals and metamaterials, and micro‐optical components. The potential of additive manufacturing applied to photonics and optoelectronics is enormous, and the field is still in its infancy. Future directions for research include the development of fully printable optical and architected materials, of effective and versatile platforms for multimaterial processing, and of high‐throughput 3D printing technologies that can concomitantly reach high resolution and large working volumes.

中文翻译:


增材制造:光子学和光电子学中的应用和方向



如今可以通过增材制造获得具有目标光学特性的材料和复杂的 3D 结构的组合,这为开发光子学和光电子学领域的新型集成系统带来了前所未有的机会。本文介绍了加工光学材料的增材技术的最新进展,重点是可实现的几何形状、可实现的空间分辨率以及可印刷光学材料的要求。展示了通过3D打印制造的光子和光电器件的相关示例,包括发光二极管、激光器、波导、光学传感器、光子晶体和超材料以及微光学元件。增材制造应用于光子学和光电子学的潜力是巨大的,而且该领域仍处于起步阶段。未来的研究方向包括开发完全可打印的光学和建筑材料、用于多材料加工的有效且多功能的平台以及可同时达到高分辨率和大工作量的高通量3D打印技术。
更新日期:2018-09-16
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