Linear polarizer design for application in the far-ultraviolet spectral range

Optical Engineering + Applications Pub Date : 2023-10-04 DOI:10.1117/12.2676820

Mateo F. Batkis, M. Quijada, P. Scowen, R. Woodruff, L. V. Rodríguez de Marcos, J. D. Del Hoyo, Johnathan Gamaunt

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Abstract

New mission concepts that are under consideration by NASA call for the design and implementation of Far Ultraviolet (FUV) polarizer technologies that have not been developed yet. A team that includes members from the NASA Goddard Space Flight Center (GSFC), Arizona State University (ASU), and Woodruff Consulting, worked on the design and development of a polarizer design that produce very high extinction ratios in the FUV spectral range (100-200 nm). This polarizer consists of reflecting light through a series of mirrors from a combination of two silicon carbide (SiC) and two lithium fluoride (LiF) crystals positioned at angles of incidence (relative to surface normal) close to the average LiF Brewster’s angle in the FUV. The output is a highly linearly polarized beam. This polarizer concept was fabricated and tested in the existing McPherson 225 Vacuum Ultraviolet (VUV) spectrometer located in the Optics Branch at NASAGSFC. Initial testing using a MgF2 crystal at the Brewster’s angle as an analyzer has shown that this design can produce state-of-the-art extinction ratios at the Hydrogen Lyman-Alpha (Ly-α) wavelength of 121.6 nm, and that the measured extinction ratio of the two crossed polarizers, ≈114, is mostly limited by the MgF2 analyzer. A polarizer with such a performance at this wavelength has never been reported and it signifies a breakthrough in FUV polarization technology. The levels of effectiveness paired with the polarizer’s compact design allows for a new polarizer capability that would one day be implemented in a future FUV spectropolarimetry space mission.

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应用于远紫外光谱范围的线性偏振器设计

NASA正在考虑的新任务概念要求设计和实施尚未开发的远紫外线(FUV)偏振器技术。来自美国宇航局戈达德太空飞行中心(GSFC)、亚利桑那州立大学(ASU)和伍德拉夫咨询公司(Woodruff Consulting)的成员组成了一个团队，致力于设计和开发一种偏光器，该偏光器在FUV光谱范围(100-200纳米)内产生非常高的消光比。该偏振器由两个碳化硅(SiC)和两个氟化锂(LiF)晶体组合的一系列反射镜组成，这些晶体的入射角(相对于表面法线)接近FUV中LiF布鲁斯特的平均角度。输出是高度线偏振光。该偏振器概念在位于NASAGSFC光学分部的现有McPherson 225真空紫外(VUV)光谱仪上制造和测试。初步测试使用MgF2晶体在布鲁斯特角作为分析仪表明，这种设计可以产生最先进的消光比在121.6 nm的氢莱曼-α (Ly-α)波长，并且测量的两个交叉偏振器的消光比≈114，主要受MgF2分析仪的限制。在该波长具有如此性能的偏振器从未被报道过，这标志着FUV偏振技术的突破。有效的水平与偏振器的紧凑设计相结合，允许有一天在未来的FUV光谱偏振测量太空任务中实现新的偏振器能力。

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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Optical Engineering + Applications

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