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Double-mirror monochromator for 4+ generation SKIF synchrotron
Russian version
E. I. Glushkov 1, A. A. Akhsakhalian1, P. A. Veprev 1, I. G. Zabrodin 1, M. V. Zorina 1, I. V. Malyshev 1, M. S. Mikhailenko 1, A. E. Pestov1, E. V. Petrakov 1, R. S. Pleshkov1, E. S. Antyushin1, V. N. Polkovnikov1, D. G. Reunov1, A. B. Ulasevich 1, A. K. Chernyshev 1, N. I. Chkhalo 1, R. A. Shaposhnikov1, Ya. V. Rakshun2,3, Yu. V. Khomyakov 2,4, V. A. Chernov2, I. P. Dolbnya 5
1Institute for Physics of Microstructures, Russian Academy of Sciences, Nizhny Novgorod, Russia
2 Budker Institute of Nuclear Physics, Siberian Branch, Russian Academy of Sciences, Novosibirsk, Russia
3Sobolev Institute of Geology and Mineralogy, Siberian Branch Russian Academy of Sciences, Novosibirsk, Russia
4SRF Siberian Circular Photon Source "SKIF", Koltsovo, Novosibirsk, Russia
5Diamond Light Source, OX11 0DE, Didcot, Great Britain
Email: eglushkov@ipmras.ru
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A double-mirror monochromator for an operating photon energy range of 10-30 keV has been developed by the Institute of Physics of Microstructures, Russian Academy of Sciences, for the 4+ generation SKIF synchrotron light source. Multilayer X-ray mirrors were used for synchrotron light monochromatization. Operating range of the device is divided into three subranges: 10-19 keV, 19-30 keV and 19-30 keV with high spectral resolution. To implement such operating mode of monochromator, three multilayer Mo/B4C, W/B4C and Cr/Be X-ray mirror strips 6 mm in height each were deposited onto substrates. Depending on the photon energy and subrange, resolution varies within 0.35 %-1.5 %. Mirror reflection coefficients are higher than 60 %. Subrange rearrangement is performed by vertical movement of mirrors. The study describes the principle of operation and design of the device, fabrication techniques used for high-precision substrates, device and components specifications. Keywords: X-ray optics, synchrotron radiation, double-mirror monochromator, multilayer X-ray mirrors.
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