Laser sintering of electrohydrodynamic inkjet-printed silver in microgravity for in-space manufacturing of electronic devices.

npj Advanced Manufacturing Pub Date : 2025-01-01 Epub Date: 2025-10-01 DOI:10.1038/s44334-025-00054-9

Ellie Schlake, Sagar Kumar Verma, Liangkui Jiang, Pengyu Zhang, Hantang Qin, Nirmala Kandadai

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Abstract

The National Aeronautics and Space Administration (NASA) plans to deploy a fully functional 3D printer in low Earth orbit for in-space manufacturing (ISM) of semiconductor electronics. Earlier, our group demonstrated the successful application of high-resolution printing for semiconductor manufacturing using electrohydrodynamic printing. However, sintering of printed films is a significant challenge due to payload constraints. In this paper, we demonstrate laser sintering as a viable technology for ISM. The first experiments of successful demonstration of laser sintering of EHD printed silver on silicon in micro and lunar gravity are presented. The microstructures and conductivity of the samples are compared to those of the ground samples, and we observe that samples under microgravity exhibit increased heat transport compared to those under gravity. We hypothesize that the samples under microgravity experience lower convective heat transport, resulting in increased surface melting. A COMSOL heat transport model supports the laser sintering studies and hypotheses.

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微重力下激光烧结电流体喷墨印刷银在空间电子器件制造中的应用。

美国国家航空航天局（NASA）计划在近地轨道上部署一台功能齐全的3D打印机，用于半导体电子产品的太空制造（ISM）。早些时候，我们的团队展示了利用电流体动力打印在半导体制造中的高分辨率打印的成功应用。然而，由于有效载荷的限制，印刷薄膜的烧结是一个重大挑战。在本文中，我们证明了激光烧结是一种可行的ISM技术。介绍了在微重力和月球重力条件下激光烧结EHD印刷银在硅上的首次成功演示实验。将样品的微观结构和电导率与地面样品进行了比较，并观察到微重力下的样品比重力下的样品表现出更大的热传递。我们假设微重力下的样品经历了较低的对流热输运，导致表面熔化增加。COMSOL热输运模型支持激光烧结的研究和假设。

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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npj Advanced Manufacturing

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