Mechanical Design Progress of the In Situ Nanoprobe Instrument for APS-U

Kearney, Steven; Chen, Si; Lai, Barry; Maser, Jörg; Mooney, Tim; Shu, Deming

doi:10.18429/JACoW-MEDSI2020-MOPC10

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RIS citation export for MOPC10: Mechanical Design Progress of the In Situ Nanoprobe Instrument for APS-U

TY  - CONF
AU  - Kearney, S.P.
AU  - Chen, S.
AU  - Lai, B.
AU  - Maser, J.
AU  - Mooney, T.
AU  - Shu, D.
ED  - Jaski, Yifei
ED  - Den Hartog, Patric
ED  - Jaje, Kelly
ED  - Schaa, Volker R.W.
TI  - Mechanical Design Progress of the In Situ Nanoprobe Instrument for APS-U
J2  - Proc. of MEDSI2020, Chicago, IL, USA, 24-29 July 2021
CY  - Chicago, IL, USA
T2  - Mechanical Engineering Design of Synchrotron Radiation Equipment and Instrumentation
T3  - 11
LA  - english
AB  - The In Situ Nanoprobe (ISN, 19-ID) beamline will be a new best-in-class long beamline to be constructed as part of the Advanced Photon Source Upgrade (APS-U) project*,**. To achieve long working distance at high spatial resolution, the ISN instrument will be positioned 210 m downstream of the x-ray source, in a dedicated satellite building, currently under construction***. The ISN instrument will use a nano-focusing Kirkpatrick-Baez (K-B) mirror system, which will focus hard x-rays to a focal spot as small as 20 nm, with a large working distance of 61 mm. The large working distance provides space for various in situ sample cells for x-ray fluorescence tomography and ptychographic 3D imaging, allows the use of a separate, independent vacuum chambers for the optics and sample, and provides the flexibility to run experiments in vacuum or at ambient pressure. A consequence of the small spot size and large working distance is the requirement for high angular stability of the KB mirrors (5 nrad V-mirror and 16 nrad H-mirror) and high relative stability between focus spot and sample (4 nmRMS). Additional features include fly-scanning a maximum of a 2 kg sample plus in situ cell at 1 mm/s in vertical and/or horizontal directions over an area of 10 mm x 10 mm. Environmental capabilities will include heating and cooling, flow of fluids and applied fields, as required for electrochemistry and flow of gases at high temperature for catalysis. To achieve these features and precise requirements we have used precision engineering fundamentals to guide the design process. We will discuss in detail the current design of the instrument focusing on the precision engineering used to achieve the stability, metrology, and positioning requirements.
PB  - JACoW Publishing
CP  - Geneva, Switzerland
SP  - 71
EP  - 74
KW  - vacuum
KW  - optics
KW  - synchrotron
KW  - ISOL
KW  - controls
DA  - 2021/10
PY  - 2021
SN  - 2673-5520
SN  - 978-3-95450-229-5
DO  - doi:10.18429/JACoW-MEDSI2020-MOPC10
UR  - https://jacow.org/medsi2020/papers/mopc10.pdf
ER  -