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Compound X-ray amorphous radiation-cooled filter based on free-standing thin films for synchrotron radiation facilities

Russian version

Khomyakov Yu. V.

¹, Rakshun Ya. V.

^1,2, Gorbachev M. V.

³, Kutkin O. M. ³, Chernov V. A.¹

¹Budker Institute of Nuclear Physics, Siberian Branch, Russian Academy of Sciences, Novosibirsk, Russia
²Siberian State University of Telecommunications and Information Science, Novosibirsk, Russia
³Novosibirsk State Technical University, Novosibirsk, Russia

Email: yu.v.khomyakov@yandex.ru, ya.v.rakshun@inp.nsk.su, m.gorbachev@corp.nstu.ru, kutkino@list.ru, v.a.chernov@mail.ru

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A radiation-cooled X-ray amorphous filter based on thin films is proposed for use at 4th generation synchrotron radiation facilities` beamlines. This filter can be exploited under conditions of high thermal loads and high coherent photon flux fraction. In order to ensure X-ray amorphousness, it is proposed to use glassy carbon, metallic glasses, and multilayers with nano-sized periods as filter materials. Filtering is assumed to be carried out in stages: first, radiation in the low-energy range (up to ~5 keV), and then, if necessary, in the medium-energy range (up to ~15 keV) being suppressed. It is proposed to use a set of glassy carbon films as an absorber for primary filtering and a set of films containing elements with higher atomic numbers for additional filtering. The selection of filter film materials allows for consistent suppression of undulator harmonics when operating in the high-energy range (above 15 keV). Modeling of thermal loads and stationary temperature distribution has been carried out for glassy carbon films. The thickness of these radiation-cooled films is chosen in such a way that their maximum temperature in thermal equilibrium does not exceed the graphitization temperature. Keywords: X-ray filter, X-ray amorphousness, radiative cooling, synchrotron radiation, undulator radiation.

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