Optical verification experiments of sub-scale starshades

arXiv: Instrumentation and Methods for Astrophysics Pub Date : 2020-11-09 DOI:10.1117/1.JATIS.7.2.021207

A. Harness, S. Shaklan, P. Willems, N. Kasdin, K. Balasubramanian, P. Dumont, V. White, K. Yee, R. Muller, Michael B. Galvin

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引用次数: 12

Abstract

Starshades are a leading technology to enable the detection and spectroscopic characterization of Earth-like exoplanets. In this paper we report on optical experiments of sub-scale starshades that advance critical starlight suppression technologies in preparation for the next generation of space telescopes. These experiments were conducted at the Princeton starshade testbed, an 80 m long enclosure testing 1/1000th scale starshades at a flight-like Fresnel number. We demonstrate 1e-10 contrast at the starshade's geometric inner working angle across 10% of the visible spectrum, with an average contrast at the inner working angle of 2.0e-10 and contrast floor of 2e-11. In addition to these high contrast demonstrations, we validate diffraction models to better than 35% accuracy through tests of intentionally flawed starshades. Overall, this suite of experiments reveals a deviation from scalar diffraction theory due to light propagating through narrow gaps between the starshade petals. We provide a model that accurately captures this effect at contrast levels below 1e-10. The results of these experiments demonstrate that there are no optical impediments to building a starshade that provides sufficient contrast to detect Earth-like exoplanets. This work also sets an upper limit on the effect of unknowns in the diffraction model used to predict starshade performance and set tolerances on the starshade manufacture.

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亚尺度星罩的光学验证实验

Starshades是一项领先的技术，可以对类地系外行星进行探测和光谱表征。在本文中，我们报告了亚尺度星罩的光学实验，这将为下一代空间望远镜的关键星光抑制技术的发展做准备。这些实验是在普林斯顿星罩试验台进行的，这是一个80米长的封闭试验台，在类似飞行的菲涅耳数下测试1/1000比例的星罩。在可见光谱的10%范围内，遮光罩几何内部工作角的对比度为1e-10，内部工作角的平均对比度为2.0e-10，对比度下限为2e-11。除了这些高对比度演示之外，我们还通过故意有缺陷的星阴影测试验证了衍射模型的精度超过35%。总的来说，这组实验揭示了标量衍射理论的偏差，因为光通过遮光花瓣之间的狭窄间隙传播。我们提供了一个模型，可以在低于1e-10的对比度水平下准确捕捉到这种效果。这些实验的结果表明，没有光学障碍来建立一个遮荫，提供足够的对比度来探测类地系外行星。这项工作还设定了用于预测遮光罩性能的衍射模型中未知因素影响的上限，并设定了遮光罩制造的公差。

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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arXiv: Instrumentation and Methods for Astrophysics

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