Additive manufacturing in space research: hybrid mass analyser for laser ablation ionisation mass spectrometry.

IF 3.1 2区化学 Q2 CHEMISTRY, ANALYTICAL

Journal of Analytical Atomic Spectrometry Pub Date : 2025-02-05 DOI:10.1039/d4ja00392f

Andreas Riedo, Peter Keresztes Schmidt, Nikita J Boeren, Salome Gruchola, Luca N Knecht, Marek Tulej, Peter Wurz

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Abstract

Additive manufacturing has found its way into many industrial and academic areas. In this contribution, we present an additively manufactured reflectron, integrated in a space-prototype mass analyser used in laser ablation ionisation mass spectrometry. Fused deposition modelling technology was applied to produce the reflectron's ion optical system. For the insulating parts, polylactic acid filament was used as printing material, while the conductive ion optical parts were printed using polylactic acid impregnated with carbon. Measurements were conducted on a stainless steel sample (AISI 316 L, 1.4435) and NIST SRM 661 sample to validate the performance of the reflectron. We found that this system performed nominally in terms of mass resolution and detection sensitivity. This demonstrates the suitability of 3D printing for rapid prototyping in laboratory environments. The latter is of considerable importance for future space exploration missions, as the methodology allows testing of new designs time efficiently and at reduced costs.

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空间研究中的增材制造：激光烧蚀电离质谱混合质分析器。

增材制造已经进入了许多工业和学术领域。在这篇贡献中，我们提出了一个增材制造的反射器，集成在用于激光烧蚀电离质谱分析的空间原型质分析器中。采用熔融沉积建模技术制作了反射器的离子光学系统。绝缘部件采用聚乳酸长丝作为打印材料，导电离子光学部件采用浸渍碳的聚乳酸打印。对不锈钢样品（AISI 316 L, 1.4435）和NIST SRM 661样品进行了测量，以验证反射器的性能。我们发现该系统在质量分辨率和检测灵敏度方面表现良好。这证明了3D打印在实验室环境中快速成型的适用性。后者对未来的空间探索任务具有相当重要的意义，因为该方法允许以较低的成本及时有效地测试新设计。

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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