3D微纳加工集成光子学应用 |Nanoscribe

3D微纳加工技术应用于集成光子学领域

双光子聚合技术所具有的高设计自由度，可以在各种预先构图的基板上实现波导和混合折射衍射光学器件等3D微纳加工制作。结合Nanoscribe公司的高精度定位系统，可以按设计需要精确地集成复杂的微纳结构。

预构图复杂光学结构的微纳加工应用

光学和光电组件的小型化对于实现数据通信和电信以及传感和成像的应用至关重要。通过传统的微纳3D打印来制作自由曲面透镜等其他新颖设计会有分辨率不足和光学质量表面不达标的缺陷，但是利用双光子聚合原理则可以完美解决这些问题。该技术不仅可以用于在平面基板上打印微纳米部件，还可以直接在预先设计的图案和拓扑上精确地直接打印复杂结构，包括光子集成电路，光纤尖端和预制晶片等。这种方法可以在各种材料（例如InP，SOI和Si3N4）上进行高精度的原位3D微纳加工，从而实现光学接口的小型化和无组装制造。

例如，可以应用于将自由曲面微纳光学组件直接打印到芯片上，从而连接多根光纤到一个芯片上。为了达到这个目的，必须将光收集起来，平行于芯片表面重新定向然后传输到窄波导中。而Nanoscribe公司基于双光子聚合原理的无掩模光刻系统拥有高设计自由度的特点，可以够轻松实现收集光束并传输到波导中。系统配备的高分辨率处理镜头和打印系统的编程接口可以实现耦合结构与波导的自动对准，且对准精度可达到100 nm。

Nanoscribe的Photonic Professional GT2双光子无掩模光刻系统可适用于科研和工业领域应用。我们的客户成功将微纳光学结构直接打印到光子组件上从而实现从边缘到表面的全面耦合。而全新的双光子灰度光刻系统Quantum X则可以应用于光子封装技术。更多应用相关科研项目请点击MiLiQuant 和 HandheldOCT.

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3D微纳加工创新科技

Beam-expanding microlenses on fiber arrays. The results were achieved within the MiLiQuant project. — 光纤阵列上的扩束微透镜。具体相关科研成果请查看MiLiQuant项目。

Scalable fabrication of several 3D couplers on a photonic chip. — 在光子芯片上可扩展打印多个3D耦合器。图片来自于W. Hartmann, H. Gehring, W. Pernice et al., University of Münster

SEM of a freeform 3D fiber-to-chip coupler printed by means of Nanoscribe’s Photonic Professional GT system and connected to a silicon nitride waveguide. — SEM下通过Nanoscribe公司的Photonic Professional GT打印系统制作的自由曲面3D光纤到芯片耦合器，并连接到氮化硅波导上。图片来自于H. Gehring, W. Hartmann, W. Pernice et al., University of Münster

3D-printed freeform total internal reflection mirror on the tip of a no-core fiber — 无芯光纤尖端上的3D打印自由曲面全内反射镜。图片来自于Simon Thiele, University of Stuttgart

3D model of a probe superimposed on a real OCT scan of an artery — 叠加于真实动脉OCT扫描仪上的探针3D模型。图片来自于Simon Thiele, University of Stuttgart and Jiawen Li, University of Adelaide

Rendering of freeform 3D couplers attached to a nanophotonic circuit for fiber-to-chip coupling. — 纳米光子电路上的自由曲面3D耦合器渲染图，光纤到芯片的耦合技术。图片来自于W. Hartmann, H. Gehring, W. Pernice et al., University of Münster

集成光子学领域应用

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2023/12/25

Waveguide Structures and Photon Splitters Fabricated via Direct (3 + 1)D Laser Printing

Affiliation: Moscow Institute of Physics and Technology (MIPT)

Journal: Bulletin of the Russian Academy of Sciences: Physics

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2023/12/13

Hybrid fiber–solid-state laser with 3D-printed intracavity lenses

Affiliation: University of Stuttgart

Journal: Optic Letters

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2023/12/11

Micro- and nanofabrication of dynamic hydrogels with multichannel information

Affiliation: University of Stuttgart, Max Planck Institute for Intelligent Systems Stuttgart

Journal: Nature Communications

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2023/10/20

High-spatial density snapshot imaging spectrometer enabled by 2-photon fabricated custom fiber bundles

Affiliation: Rice University, University of Southern California

Journal: Optics Letters

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2023/10/18

Novel applications based on dynamic color of photonic structures printed by two-photon lithography

Affiliation: Trinity College Dublin

Journal: Advanced Photonics Congress 2023

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2023/10/05

TPL-fabricated responsive hydrogel-based micro photonic structures for visible vapor sensing

Affiliation: College Green, the University of Dublin, Trinity College

Journal: Molecular and Nanophotonic Machines VI

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2023/09/23

3D LASER FABRICATION OF CONICAL FIBER TIPS

Affiliation: Center for Advanced Laser Technologies, Magurele, Romania

Journal: Sciences of Europe

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2023/09/21

Pick and place process for uniform shrinking of 3D printed micro- and nano-architected materials

Affiliation: Singapore University of Technology and Design, Industrial Technology Center of Wakayama Prefecture, Hunan University, National University of Singapore

Journal: Nature Communications

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2023/09/06

3D printing of plasmonic nanofocusing tip enabling high resolution, high throughput and high contrast optical near-field imaging

Affiliation: South China University of Technology, Beijing Institute of Technology

Journal: Light: Science & Applications

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2023/08/25

Refractive index measurement of IP-S and IP-Dip photoresists at THz frequencies and validation via 3D photonic metamaterials made by direct laser writing

Affiliation: Swiss Federal Laboratories for Materials Science and Technology, Foundation for Research and Technology-Hellas, University of Crete, Theoretical and Physical Chemistry Institute, Norwegian University of Science and Technology

Journal: Optical Materials Express

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