Shatokhin A. N.
1, Vishnyakov E. A.
1, Kolesnikov A. O.
1, Nikolenko A. D.2,3, Ragozin E. N.
1
1Lebedev Physical Institute, Russian Academy of Sciences, Moscow, Russia
2 Budker Institute of Nuclear Physics, Siberian Branch, Russian Academy of Sciences, Novosibirsk, Russia
3Boreskov Institute of Catalysis, Siberian Branch of RAS, Novosibirsk, Russia
Email: shatohinal@gmail.com, juk301@mail.ru, alexey6180@gmail.com, enragozin@gmail.com
A high-resolution monochromator with a broad spectral range of 125-4200 Angstrem is designed for a measuring beamline of the projected synchrotron radiation source "SKIF" (Novosibirsk). The optical configuration of the monochromator comprises a grazing-incidence concave mirror, a plane VLS grating, and an exit slit. It is planned to use two replaceable VLS gratings with central groove frequencies of 600 and 150 mm-1 intended for subranges of 125-1000 Angstrem and 900-4200 Angstrem, respectively. Wavelength tuning in each of the two subranges is carried out by solely the rotation of the VLS-gratings. Due to the proper choice of p1 VLS-grating coefficients, the focal distance varies only slightly over the entire spectral range, and the p2 VLS-grating coefficients are used to suppress the aberrations of the mirror and the gratings. The resolving power of the configuration obtained by numerical ray tracing exceeds 1000 in the 125-1000 Angstrem range and 2000 in the 900-4200 Angstrem range. Keywords: VUV, spectroscopy, VLS-grating, synchrotron radiation.
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