Asgard/NOTT：VLTI 的 L 波段归零干涉测量。II.暖光学设计和注入系统

IF 1.7 3区工程技术 Q2 ENGINEERING, AEROSPACE

Journal of Astronomical Telescopes Instruments and Systems Pub Date : 2024-02-01 DOI:10.1117/1.jatis.10.1.015002

Germain Garreau, Azzurra Bigioli, Romain Laugier, Gert Raskin, Johan Morren, Jean-Philippe Berger, Colin Dandumont, Harry-Dean Kenchington Goldsmith, Simon Gross, Michael Ireland, Lucas Labadie, Jérôme Loicq, Stephen Madden, Guillermo Martin, Marc-Antoine Martinod, Alexandra Mazzoli, Ahmed Sanny, Hancheng Shao, Kunlun Yan, Denis Defrère

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引用次数: 0

摘要

Asgard/NOTT（前身为Hi-5）是欧洲研究理事会（ERC）资助的一个项目，由鲁汶大学主持，是甚大望远镜干涉仪（VLTI）的一个新访客仪器。该项目的主要目标是利用 L′波段（3.5 至 4.0）μm 的消隐干涉测量法对年轻恒星周围的雪线区域进行成像，因为系外行星与其宿主恒星之间的对比度在该波段具有优势。突破性进展是使用了光子合束器，该合束器直到最近才能够在这一光谱范围内达到所需的 10-3 的理论原始对比度。系外行星的消隐干涉测量观测还要求 VLTI 的四个瞳孔在强度、相位和偏振方面保持高度平衡。向合束器注入光束和消隐干涉测量的要求推动了暖光学和注入系统的设计。本文介绍了直至合束器的光学设计。它提供了将 VLTI 的光有效耦合到合束仪的技术解决方案。在耦合过程中，目标是将吞吐量损失限制在最佳预期注入效率的 5%。为实现这一目标，考虑了一系列不同的损耗源及其对注入效率的影响。此外，还提出了一些解决方案，以满足光束平衡对强度、相位和偏振的要求。还列出了设计的不同特性，包括所使用的光学器件、它们的校准和公差，以及它们在吞吐量和无效深度方面对仪器性能的影响。性能评估结果表明，预计注入的吞吐量损失小于最佳效率的 6.4%，空洞深度为 2.10-3 ∼，主要来自本工作范围之外的光路延迟误差。

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Asgard/NOTT: L-band nulling interferometry at the VLTI. II. Warm optical design and injection system

Asgard/NOTT (previously Hi-5) is a European Research Council (ERC)-funded project hosted at KU Leuven and a new visitor instrument for the Very Large Telescope Interferometer (VLTI). Its primary goal is to image the snow line region around young stars using nulling interferometry in the L′-band (3.5 to 4.0) μm, where the contrast between exoplanets and their host stars is advantageous. The breakthrough is the use of a photonic beam combiner, which only recently allowed the required theoretical raw contrast of 10−3 in this spectral range. Nulling interferometry observations of exoplanets also require a high degree of balancing between the four pupils of the VLTI in terms of intensity, phase, and polarization. The injection into the beam combiner and the requirements of nulling interferometry are driving the design of the warm optics and the injection system. The optical design up to the beam combiner is presented. It offers a technical solution to efficiently couple the light from the VLTI into the beam combiner. During the coupling, the objective is to limit throughput losses to 5% of the best expected efficiency for the injection. To achieve this, a list of different loss sources is considered with their respective impact on the injection efficiency. Solutions are also proposed to meet the requirements of beam balancing for intensity, phase, and polarization. The different properties of the design are listed, including the optics used, their alignment and tolerances, and their impact on the instrumental performances in terms of throughput and null depth. The performance evaluation gives an expected throughput loss <6.4% of the best efficiency for the injection and a null depth of ∼2.10−3, mainly from optical path delay errors outside the scope of this work.

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来源期刊

Journal of Astronomical Telescopes Instruments and Systems Engineering-Mechanical Engineering

CiteScore

4.40

自引率

13.00%

发文量

119

期刊介绍： The Journal of Astronomical Telescopes, Instruments, and Systems publishes peer-reviewed papers reporting on original research in the development, testing, and application of telescopes, instrumentation, techniques, and systems for ground- and space-based astronomy.