Artemis-enabled Stellar Imager (AeSI): A Lunar Long-Baseline UV/Optical Imaging Interferometer

arXiv - PHYS - Instrumentation and Methods for Astrophysics Pub Date : 2024-08-08 DOI:arxiv-2408.04699

Gioia Rau, Kenneth G. Carpenter, Tabitha Boyajian, Michelle Creech-Eakman, Julianne Foster, Margarita Karovska, David Leisawitz, Jon A. Morse, David Mozurkewich, Sarah Peacock, Noah Petro, Paul Scowen, Breann Sitarski, Gerard van Belle, Erik Wilkinson

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Abstract

NASA's return to the Moon presents unparalleled opportunities to advance high-impact scientific capabilities. At the cutting edge of these possibilities are extremely high-resolution interferometric observations at visible and ultraviolet wavelengths. Such technology can resolve the surfaces of stars, explore the inner accretion disks of nascent stars and black holes, and eventually enable us to observe surface features and weather patterns on nearby exoplanets. We have been awarded Phase 1 support from NASA's Innovative Advanced Concepts (NIAC) program to explore the feasibility of constructing a high-resolution, long-baseline UV/optical imaging interferometer on the lunar surface, in conjunction with the Artemis Program. A 1996 study comparing interferometers on the Moon versus free-flyers in space concluded that, without pre-existing lunar infrastructure, free-flyers were preferable. However, with the advent of the Artemis Program, it is now crucial to revisit the potential of building lunar interferometers. Our objective is to conduct a study with the same level of rigor applied to large baseline, free-flying interferometers during the 2003-2005 NASA Vision Missions Studies. This preparation is essential for timely and effective utilization of the forthcoming lunar infrastructure. In this paper, we highlight the groundbreaking potential of a lunar surface-based interferometer. This concept study will be a huge step forward to larger arrays on both the moon and free-flying in space, over a wide variety of wavelengths and science topics. Our Phase 1 study began in April 2024, and here we present a concise overview of our vision and the progress made so far.

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Artemis-enabled Stellar Imager (AeSI)：月球长基线紫外线/光学成像干涉仪

美国国家航空航天局重返月球为推进具有重大影响的科学能力提供了无与伦比的机会。这些可能性的最前沿是可见光和紫外线波长的极高分辨率干涉测量观测。这种技术可以分辨恒星的表面，探索新生恒星和黑洞的内部吸积盘，并最终使我们能够观测近邻系外行星的表面特征和气候模式。我们已经获得了美国宇航局创新先进概念（NIAC）计划的第一阶段支持，与阿特米斯计划一起探索在月球表面建造高分辨率、长基线紫外线/光学成像干涉仪的可行性。1996 年的一项研究对月球上的干涉仪和太空中的自由飞行器进行了比较，得出的结论是，在没有预先存在的月球基础设施的情况下，自由飞行器更为可取。然而，随着阿特米斯计划的到来，现在重新审视建造月球干涉仪的潜力至关重要。我们的目标是开展一项研究，其严谨程度与 2003-2005 年美国宇航局愿景任务研究期间对大型基线、自由飞行干涉仪的研究相同。这项准备工作对于及时有效地利用即将到来的月球基础设施至关重要。在本文中，我们强调了月球表面干涉仪的突破性潜力。这项概念研究将为在月球上和太空中自由飞行的更大阵列迈出一大步，并将涵盖各种波长和科学主题。我们的第一阶段研究始于 2024 年 4 月，在此我们将简要概述我们的愿景和迄今为止取得的进展。

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 - PHYS - Instrumentation and Methods for Astrophysics

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