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Abstract

The slit imaging spectrometer is one of the important tools for solar extreme ultraviolet (EUV) spectral imaging detection. However, at present, there is no such instrument load in China. The research of solar physics and space weather in the field of EUV spectral diagnosis mainly depends on foreign instrument data, which seriously restricts the development of related disciplines. The spectral imaging instruments that have been launched internationally have only a spatial resolution of $2''$ , and it is difficult to observe the core characteristics of the plasma related to the coronal heating mechanism predicted by the theoretical model. In order to better understand the coupling process between different layers of the sun’s atmosphere, solar physics research requires the observed data with wider spectral coverage. In light of this, we propose and design a sub-angular second spatially resolved solar extreme ultraviolet broadband imaging spectrometer operating in a band range of 62–80 nm and 92–110 nm. Compared with the existing instruments, the system can achieve high spatial resolution and spectral resolution, and wide spectral range coverage. Performance evaluation results indicate that the imaging spectrometer’s spatial resolutions in both bands are better than 0.4 '', and their spectral resolutions are both better than 0.007 nm, with spectral imaging quality approaching the diffraction limit. The system designed in this work holds significant reference value for developing the first Chinese space-based solar EUV spectroscopic instrument in the future.

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Authors and contacts

Corresponding author:Xing Yang-Guang,xyg@bit.edu.cn

Funds:Project supported by the National Natural Science Foundation of China (Grant Nos. 62205027, 42274208) and the Strategic Priority Research Program of the Chinese Academy of Sciences (Grant No. XDA15018300).

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Performance parameters	Design values
Satellite orbit	Dawn-dusk solar synchronous orbit
Entrance aperture/mm²	156 × 156
Slit FOV/('')	4.8
Wavelength range/nm	62—80 & 92—110 & 46—55 (2nd order)
Spectral resolution/nm	≤ 0.007
Spatial plate scale/(('')·pixel^–1)	≤ 0.5
Spatial resolution/('')	≤ 1.0
System focal length/mm	11000
Optical volume/mm³	≤ 2800 × 500 × 450
Pixel size of detector/μm	15 (1536 × 1536)

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Specification
Wavelength range@SW/nm	62—80
Wavelength range@LW/nm	92—110 & 46—55 (2nd order)
Spectral resolution@SW/nm	0.00615
Spectral resolution@LW/nm	0.00642
Spatial plate scale @SW/(('')·pixel^–1)	0.340(@71 nm)
Spatial plate scale @LW/(('')·pixel^–1)	0.382(@101 nm)
System focal length/mm	11000
Optical volume/mm³	2600 × 420 × 400
Detector/μm	15 (1536 × 1536)
Telescope design
Aperture/mm²	156 × 156
R_T/mm	4320.025
Conic	–1
$\varDelta $/mm	120
Slit design
Slits width/('')	0.28, 1, 2, 40
Slits length/('')	288
Raster coverage/('')	±144
TVLS grating design
m	+1 order
1/d₀/mm^–1	1500
β	5.177×@SW; 5.261×@LW
i/(°)	0.909
r_A/mm	440.667
R/mm	735.545
ρ/mm	737.138
b₂	0.0349
Groove density/(lines·mm^–1)	1500 ± 4
Ruling area/mm²	36 × 36
Two independent detectors design
Wavelength range/nm	Tilt angle/(°)
62—80	15.259
92—110	17.824

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Component	Tolerance items	Values of tolerances
Primary mirror	Surface irregularity (RMS)	λ/20 (λ= 632.8 nm)
	Conic	±0.005
	Radius of curvature/mm	±3.6
	Microroughness (RMS)/nm	0.4
	Element decenter/μm	±50
	Element tilt/('')	±15
TVLS grating	Substrate irregularity (RMS)	λ/30 (λ= 632.8 nm)
	Line density/ (groove·mm^–1)	±0.65
	Radius of curvature/mm	±0.3
	Microroughness (RMS)/nm	0.8
	Element decenter/μm	±20
	Element tilt/('')	±60
Slit assembly	Element decenter/μm	±20
Slit assembly	Element tilt/(°)	±0.03

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Vol. 73, Issue 3 - 2024-02-05

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