High-heat-load monochromator options for the RIXS beamline at the APS with the MBA lattice | Zendy

Zunping Liu | Zendy; T. Gög | Zendy; Stanislav Stoupin | Zendy; M. H. Upton | Zendy; Yang Ding | Zendy; Jung-Ho Kim | Zendy; D. Casa | Zendy; Ayman Said | Zendy; Jason A. Carter | Zendy; Gary Navrotski | Zendy

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High-heat-load monochromator options for the RIXS beamline at the APS with the MBA lattice

Author(s) -

Zunping Liu,

T. Gög,

Stanislav Stoupin,

M. H. Upton,

Yang Ding,

Jung-Ho Kim,

D. Casa,

Ayman Said,

Jason A. Carter,

Gary Navrotski

Publication year - 2016

Publication title -

aip conference proceedings

Language(s) - English

Resource type - Conference proceedings

eISSN - 1551-7616

pISSN - 0094-243X

DOI - 10.1063/1.4952918

Subject(s) - monochromator , beamline , diamond , optics , materials science , optoelectronics , beam (structure) , physics , composite material , wavelength

With the MBA lattice for APS-Upgrade, tuning curves of 2.6 cm period undulators meet the source requirements for the RIXS beamline. The high-heat-load monochromator (HHLM) is the first optical white beam component. There are four options for the HHLM such as diamond monochromators with refrigerant of either water or liquid nitrogen (LN2), and silicon monochromators of either direct or indirect cooling system. Their performances are evaluated at energy 11.215 keV (Ir L-III edge). The cryo-cooled diamond monochromator has similar performance as the water-cooled diamond monochromator because GaIn of the Cu-GaIn-diamond interface becomes solid. The cryo-cooled silicon monochromators perform better, not only in terms of surface slope error due to thermal deformation, but also in terms of thermal capacity.

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