Optical and thermal design of 1.5-m aperture solar UV visible and IR observing telescope for Solar-C mission

Y. Suematsu; Y. Katsukawa; T. Shimizu; K. Ichimoto; T. Horiuchi; Y. Matsumoto; N. Takeyama

doi:10.1117/12.2309191

20 November 2017 Optical and thermal design of 1.5-m aperture solar UV visible and IR observing telescope for Solar-C mission

Y. Suematsu, Y. Katsukawa, T. Shimizu, K. Ichimoto, T. Horiuchi, Y. Matsumoto, N. Takeyama

Author Affiliations +

Proceedings Volume 10565, International Conference on Space Optics — ICSO 2010; 105650R (2017) https://doi.org/10.1117/12.2309191
Event: International Conference on Space Optics—ICSO 2010, 2010, Rhodes Island, Greece

Abstract

The next Japanese solar mission, SOLAR-C, which has been envisaged after successful science operation of Hinode (SOLAR-B) mission, is perusing two plans: plan-A and plan-B, and under extensive study from science objectives as well as engineering point of view. The plan-A aims at performing out-of-ecliptic observations for investigating, with helioseismic approach, internal structure and dynamo mechanisms of the Sun. It also explores polar regions where fast solar wind is believed to originate. A baseline orbit for plan-A is a circular orbit of 1 AU distance from the Sun with its inclination at around or greater than 40 degrees. The plan-B aims to study small-scale plasma processes and structures in the solar atmosphere which attract researchers’ growing interest, followed by many Hinode discoveries [1], for understanding fully dynamism and magnetic nature of the atmosphere. With plan-B, high-angular-resolution investigation of the entire solar atmosphere (from the photosphere to the corona, including their interface layers, i.e., chromosphere and transition region) is to be performed with enhanced spectroscopic and spectro-polarimetric capability as compared with Hinode, together with enhanced sensitivity towards ultra-violet wavelengths. The orbit of plan-B is either a solar synchronous polar orbit of altitude around 600 km or a geosynchronous orbit to ensure continuous solar observations. After the decision of any one of the two plans, the SOLAR-C will be proposed for launch in mid-2010s.

In this paper, we will present a basic design of one of major planned instrumental payload for the plan-B: the Solar Ultra-violet Visible and near IR observing Telescope (hereafter referred to as SUVIT). The basic concept in designing the SUVIT is to utilize as much as possible a heritage of successful telescope of the Solar Optical Telescope (SOT) aboard Hinode [2]. Major differences of SUVIT from SOT are the three times larger aperture of 1.5 m, which enables to collect one order of magnitude more photons than SOT, relatively shorter telescope length of 2.8 m to accommodate a launcher’s nosecone size for possible dual-satellite-launch configuration, and much wider observing wavelength from UV (down to 250 nm) through near IR (up to 1100 nm). The large aperture is essentially important to attain scientific goals of the plan-B, especially for accurate diagnostics of the dynamic solar chromosphere as revealed by Hinode, although this make it difficult to design the telescope because of ten times more solar heat load introduced into the telescope. The SUVIT consists of two optically separable components; the telescope assembly (TA) and an accompanying focal plane package equipped with filtergraphs and spectrographs. Opto-mechanical and -thermal performance of the TA is crucial to attain high-quality solar observations and here we present a status of feasible study in its optical and thermal designing for diffraction-limited performance at visible wavelength in a reasonably wide field of view.

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Y. Suematsu, Y. Katsukawa, T. Shimizu, K. Ichimoto, T. Horiuchi, Y. Matsumoto, and N. Takeyama "Optical and thermal design of 1.5-m aperture solar UV visible and IR observing telescope for Solar-C mission", Proc. SPIE 10565, International Conference on Space Optics — ICSO 2010, 105650R (20 November 2017); https://doi.org/10.1117/12.2309191

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