Preliminary characterisation of the HEXITECMHz spectroscopic X-ray imaging detector

Preliminary characterisation of the HEXITECMHz spectroscopic X-ray imaging detector

The HEXITECMHz ASIC is the next generation of the STFC's High Energy X-ray Imaging Technology (HEXITEC). With a ×100 increase in the camera frame rate to 1 MHz, the new ASIC is capable of delivering fully spectroscopic X-ray imaging at photon fluxes of 2×106 photons s-1 mm-2. The improved flux...

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Veröffentlicht in:Journal of instrumentation 2023-07, Vol.18 (7), p.P07048
Hauptverfasser: Veale, M.C., Bell, S., Cline, B.D., Church, I., Cross, S., Day, C., French, M., Gardiner, T., Ghorbanian, N., Hart, M.D., Jones, L.L., Lipp, J., Nicholls, T., Nobes, J., Prydderch, M., Schneider, A., Seller, P., Sole, D., Wilson, M.D., Dhamgaye, V., Fox, O., Sawhney, K.
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Cadmium zinc tellurides
Detectors
Diamonds
Energy resolution
Fluxes
Front-end electronics for detector readout
Instrumentation for synchrotron radiation accelerators
Light sources
Photons
Pixels
Prototype tests
Solid state detectors
Synchrotrons
X ray imagery
X-rays
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container_end_page
container_issue 7
container_start_page P07048
container_title Journal of instrumentation
container_volume 18
creator Veale, M.C.
Bell, S.
Cline, B.D.
Church, I.
Cross, S.
Day, C.
French, M.
Gardiner, T.
Ghorbanian, N.
Hart, M.D.
Jones, L.L.
Lipp, J.
Nicholls, T.
Nobes, J.
Prydderch, M.
Schneider, A.
Seller, P.
Sole, D.
Wilson, M.D.
Dhamgaye, V.
Fox, O.
Sawhney, K.
description The HEXITECMHz ASIC is the next generation of the STFC's High Energy X-ray Imaging Technology (HEXITEC). With a ×100 increase in the camera frame rate to 1 MHz, the new ASIC is capable of delivering fully spectroscopic X-ray imaging at photon fluxes of 2×106 photons s-1 mm-2. The improved flux capability ensures the relevance of the technology at a new generation of difraction-limited storage ring (DLSR) synchrotrons as well as enabeling dynamic spectroscopic imaging with sub-keV energy resolution to be carried out on millisecond timescales. In this paper preliminary results from X-ray testing of a 0.3 mm thick p-type Si sensor and 2.0 mm thick HF-CdZnTe sensor at the Diamond Light Source Synchrotron are presented for the first time. Each module consists of 80 × 80 pixels on a 250 μm pixel pitch operated at a temperature of 20°C and a frame rate of 1 MHz. For these preliminary measurements, testing was completed using a prototype test system which limited readout to a portion of the 1 MHz output sampled over an SPI test interface at ∼50 Hz. Despite this limitation these measurements allow the spectroscopic performance of the ASIC to be characterised ahead of the full DAQ system. The prototype detectors were characterised using monochromatic X-rays with energies 12–35 keV at fluxes of (0.6 – 2.5) × 106 photons s-1 mm-2. At an X-ray energy of 12 keV, the energy resolution of the p-type Si and HF-CdZnTe detectors were measured to be 1.0 keV and 1.1 keV respectively. At the higher energies of 20 keV and 35 keV the energy resolution in the HF-CdZnTe was measured to be 1.2 keV and 1.4 keV respectively.
doi_str_mv 10.1088/1748-0221/18/07/P07048
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Instrum</addtitle><date>2023-07-01</date><risdate>2023</risdate><volume>18</volume><issue>7</issue><spage>P07048</spage><pages>P07048-</pages><eissn>1748-0221</eissn><abstract>The HEXITECMHz ASIC is the next generation of the STFC's High Energy X-ray Imaging Technology (HEXITEC). With a ×100 increase in the camera frame rate to 1 MHz, the new ASIC is capable of delivering fully spectroscopic X-ray imaging at photon fluxes of 2×106 photons s-1 mm-2. The improved flux capability ensures the relevance of the technology at a new generation of difraction-limited storage ring (DLSR) synchrotrons as well as enabeling dynamic spectroscopic imaging with sub-keV energy resolution to be carried out on millisecond timescales. In this paper preliminary results from X-ray testing of a 0.3 mm thick p-type Si sensor and 2.0 mm thick HF-CdZnTe sensor at the Diamond Light Source Synchrotron are presented for the first time. Each module consists of 80 × 80 pixels on a 250 μm pixel pitch operated at a temperature of 20°C and a frame rate of 1 MHz. For these preliminary measurements, testing was completed using a prototype test system which limited readout to a portion of the 1 MHz output sampled over an SPI test interface at ∼50 Hz. Despite this limitation these measurements allow the spectroscopic performance of the ASIC to be characterised ahead of the full DAQ system. The prototype detectors were characterised using monochromatic X-rays with energies 12–35 keV at fluxes of (0.6 – 2.5) × 106 photons s-1 mm-2. At an X-ray energy of 12 keV, the energy resolution of the p-type Si and HF-CdZnTe detectors were measured to be 1.0 keV and 1.1 keV respectively. At the higher energies of 20 keV and 35 keV the energy resolution in the HF-CdZnTe was measured to be 1.2 keV and 1.4 keV respectively.</abstract><cop>Bristol</cop><pub>IOP Publishing</pub><doi>10.1088/1748-0221/18/07/P07048</doi><tpages>20</tpages><oa>free_for_read</oa></addata></record>
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source IOP Publishing Journals; Institute of Physics (IOP) Journals - HEAL-Link
subjects Cadmium zinc tellurides
Detectors
Diamonds
Energy resolution
Fluxes
Front-end electronics for detector readout
Instrumentation for synchrotron radiation accelerators
Light sources
Photons
Pixels
Prototype tests
Solid state detectors
Synchrotrons
X ray imagery
X-rays
title Preliminary characterisation of the HEXITECMHz spectroscopic X-ray imaging detector
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