20 cm Sealed Tube Photon Counting Detectors with Novel Microchannel Plates for Imaging and Timing Applications

As part of a collaborative program between University of California, Berkeley, the Argonne National Laboratory, University of Chicago, and several commercial companies, a 20cm square sealed tube microchannel plate detector scheme with a proximity focused bialkali photocathode is being developed. Sea...

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Bibliographic Details
Published in:Physics procedia 2012, Vol.37, p.803-810
Main Authors: Siegmund, O.H.W., McPhate, J.B., Tremsin, A.S., Jelinsky, S.R., Frisch, H.J., Elam, J., Mane, A., Wagner, R., Minot, M.J., Renaud, J., Deterando, M.
Format: Article
Language:English
Subjects:
atomic layer deposition
imaging
Microchannel plate
photocathode
photon counting
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Summary:As part of a collaborative program between University of California, Berkeley, the Argonne National Laboratory, University of Chicago, and several commercial companies, a 20cm square sealed tube microchannel plate detector scheme with a proximity focused bialkali photocathode is being developed. Sealed tube microchannel plate deviceshave good imaging and timing characteristics, but large areas have been previously unavailable. We have madeb considerable progress in fabricating large size microchannel plates. A key feature is the novel implementation of low cost microchannel plates using borosilicate micro-capillary arrays with hollow core tubes. The resistive and secondary electron emissive surfaces are then applied by atomic layer deposition, eliminating the wet etch and thermal reduction processes for normal glass microchannel plates. Initial results with 33mm format microchannel plates for gain, pulse width, imaging performance and lifetime are comparable to conventional MCPs. Large 20cm square microchannel plate prototypes with 20μm and 40μm pores have been fabricated and initial tests show operational gain. Design and fabrication of a 20cm sealed tube assembly is well advanced and comprises a borosilicate entrance window, a proximity focused bialkali photocathode, a pair of microchannel plates and a stripline readout anode. The design employs a brazed ceramic walled enclosure and a transfer tube type photocathode with an indium seal. We have adopted a baseline bialkali photocathode to match the anticipated input spectrum, and have made a number of test cathodes with >20% peak quantum efficiency on borofloat-33 window material. Stripline anodes are also being developed which will give less than 1mm spatial resolution using custom ASIC amplification and timing electronics.
ISSN:1875-3892
1875-3892
DOI:10.1016/j.phpro.2012.03.722