In Situ Multiphysical Metrology for Photonic Wire Bonding by Two-Photon Polymerization.

IF 3.1 3区 材料科学 Q3 CHEMISTRY, PHYSICAL
Materials Pub Date : 2024-10-31 DOI:10.3390/ma17215297
Yu Lei, Wentao Sun, Xiaolong Huang, Yan Wang, Jinling Gao, Xiaopei Li, Rulei Xiao, Biwei Deng
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Abstract

Femtosecond laser two-photon polymerization (TPP) technology, known for its high precision and its ability to fabricate arbitrary 3D structures, has been widely applied in the production of various micro/nano optical devices, achieving significant advancements, particularly in the field of photonic wire bonding (PWB) for optical interconnects. Currently, research on optimizing both the optical loss and production reliability of polymeric photonic wires is still in its early stages. One of the key challenges is that inadequate metrology methods cannot meet the demand for multiphysical measurements in practical scenarios. This study utilizes novel in situ scanning electron microscopy (SEM) to monitor the working PWBs fabricated by TPP technology at the microscale. Optical and mechanical measurements are made simultaneously to evaluate the production qualities and to study the multiphysical coupling effects of PWBs. The results reveal that photonic wires with larger local curvature radii are more prone to plastic failure, while those with smaller local curvature radii recover elastically. Furthermore, larger cross-sectional dimensions contribute dominantly to the improved mechanical robustness. The optical-loss deterioration of the elastically deformed photonic wire is only temporary, and can be fully recovered when the load is removed. After further optimization based on the results of multiphysical metrology, the PWBs fabricated in this work achieve a minimum insertion loss of 0.6 dB. In this study, the multiphysical analysis of PWBs carried out by in situ SEM metrology offers a novel perspective for optimizing the design and performance of microscale polymeric waveguides, which could potentially promote the mass production reliability of TPP technology in the field of chip-level optical interconnection.

通过双光子聚合实现光子导线键合的原位多物理计量学。
飞秒激光双光子聚合(TPP)技术以其高精度和制造任意三维结构的能力而著称,已被广泛应用于各种微/纳米光学器件的生产,并取得了重大进展,尤其是在用于光互连的光子线键合(PWB)领域。目前,有关优化聚合物光子线光学损耗和生产可靠性的研究仍处于早期阶段。其中一个主要挑战是,不完善的计量方法无法满足实际应用中对多重物理测量的需求。本研究利用新型原位扫描电子显微镜 (SEM) 在微观尺度上监测通过 TPP 技术制造的工作 PWB。同时进行光学和机械测量,以评估生产质量并研究 PWB 的多物理耦合效应。结果表明,局部曲率半径较大的光子线更容易发生塑性破坏,而局部曲率半径较小的光子线则能弹性恢复。此外,横截面尺寸越大,机械稳健性越好。弹性变形光子线的光损耗劣化只是暂时的,在移除负载后可以完全恢复。根据多物理量测量结果进一步优化后,本研究中制造的 PWB 的插入损耗最小可达 0.6 dB。在这项研究中,通过原位 SEM 计量法对 PWB 进行的多物理场分析为优化微尺度聚合物波导的设计和性能提供了一个新的视角,有可能促进 TPP 技术在芯片级光互连领域的量产可靠性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Materials
Materials MATERIALS SCIENCE, MULTIDISCIPLINARY-
CiteScore
5.80
自引率
14.70%
发文量
7753
审稿时长
1.2 months
期刊介绍: Materials (ISSN 1996-1944) is an open access journal of related scientific research and technology development. It publishes reviews, regular research papers (articles) and short communications. Our aim is to encourage scientists to publish their experimental and theoretical results in as much detail as possible. Therefore, there is no restriction on the length of the papers. The full experimental details must be provided so that the results can be reproduced. Materials provides a forum for publishing papers which advance the in-depth understanding of the relationship between the structure, the properties or the functions of all kinds of materials. Chemical syntheses, chemical structures and mechanical, chemical, electronic, magnetic and optical properties and various applications will be considered.
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