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Ionization parameters of Trimethylbismuth for high-energy photon detection

Abstract : CaLIPSO is an innovative photon detector concept designed for high precision brain PET imaging. For the first time, liquid trimethylbismuth is used as sensitive medium. The detector operates as a time-projection chamber and detects both Cherenkov light and charge signal. Indeed, each 511-keV photon releases a single primary electron that triggers a Cherenkov radiation and ionizes the medium. As trimethylbismuth has never been studied before, we measured its free ion yield defined as the number of electron–ion pairs released by the primary electron. To this end, we developed a low-noise measuring system to determine the weak current induced by a 60Co source in the liquid with an accuracy better than 5 fA for an electric field up to 7 kV/cm. We used tetramethylsilane as benchmark liquid to validate the apparatus and we measured a zero-field free ion yield of 0.53 +/−0.03 in agreement with literature. However, we found a zero-field free ion yield of 0.083 +/−0.003 for trimethylbismuth, which is a factor 7 lower than the typical values for similar dielectric liquids. Quantum chemistry computations on heavy atoms tend to demonstrate the high ability of trimethylbismuth to capture electrons, which could explain this weak value. This recombination mechanism marks a new step in understanding charge transport in liquid detectors. Finally, to verify the detectability of individual charge pulses, we developed a charge pulse measurement system which has been successfully validated with TMSi. Measurements with TMBi are ongoing.
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Contributor : Serge Palacin Connect in order to contact the contributor
Submitted on : Tuesday, August 9, 2022 - 4:48:12 PM
Last modification on : Wednesday, August 24, 2022 - 2:46:52 PM

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M. Farradèche, G. Tauzin, J-Ph. Mols, J-P. Bard, J-P. Dognon, et al.. Ionization parameters of Trimethylbismuth for high-energy photon detection. Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, Elsevier, 2020, 958, pp.162646. ⟨10.1016/j.nima.2019.162646⟩. ⟨cea-03748580⟩



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