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Home » Technical Physics » Year 2022, issue 13 » Article p. 2085
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Manufacturing and research of mirrors with a wide bandwidth for synchrotron applications
Russian version
DOI: 10.21883/TP.2022.13.52227.128-21
Akhsakhalyan A. A.1, Garakhin S. A.1, Dar'in F. A.2, Zorina M. V.1, Kriventsov V. V.2, Pershin D. D.3, Pestov A. E.1, Pleshkov R. S.1, Polkovnikov V. N.1, Rakshun Ya. V.2, Salashchenko N. N.1, Svetokhin S. S2, Svechnikov M. V.1, Sorokoletov D. S.2, Chernov V. A.2, Chkhalo N. I.1
1Institute for Physics of Microstructures, Russian Academy of Sciences, Nizhny Novgorod, Russia
2Budker Institute of Nuclear Physics, Siberian Branch, Russian Academy of Sciences, Novosibirsk, Russia
3Novosibirsk State University, Novosibirsk, Russia
Email: GarakhinS@yandex.ru
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The work is devoted to the development, fabrication and analysis of broadband W / Si multilayer mirrors for a broadband monochromator, calculated for the spectral range of 7-10 keV. The possibility of using the stacking approach to obtain multilayer mirrors with a reflection coefficient of about 30% and a spectral bandwidth Delta E/E of about 20% is shown. The results of measurements of the angular and spectral reflection curves of the mirror obtained on a laboratory diffractometer and on a synchrotron in Novosibirsk are presented. Keywords: hard X-ray range, monochromator, synchrotron radiation, broadband mirrors, stack structures, multilayer X-ray mirrors.
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