Self-Cooling of a Large Gaseous Detector
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Large volume gas detectors are common for particle tracking in high energy physics experiments. We discuss the possibility to use the internal ionization gas also as a coolant fluid to remove the heat produced by an integrated front-end (FE) readout electronics. The technique is based on an optimized fluid dynamics and is applicable to modern low-power electronics. The advantages are a simplified detector design, an overall lower material budget within the tracking detector, as well as reduced costs. We consider the case study of a straw tube tracker and optimize the relevant cooling parameters with thermal analyses. Our results indicate that an efficient cooling can be achieved with maximal operating temperatures below 400C for the electronic components, using a gas mixture containing up to 30% of CO2 and relatively modest values of the gas flow.
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