dorsal/arxiv
View SchemaLuminescent Bolometer and Neutrino Physics
| Authors | Luis Gonzalez-Mestres |
|---|---|
| Categories | |
| ArXiv ID | physics/9711025 |
| URL | https://arxiv.org/abs/physics/9711025 |
Abstract
The luminescent bolometer, proposed in 1988, is now seriously considered for several applications in nuclear and particle physics: dark matter searches, double beta decays, low energy neutrino physics, heavy ion physics... It is also a very promising device for basic condensed-matter physics and chemistry experiments, and may lead to astrophysical applications. The luminescent bolometer is based on the simultaneous detection of light and phonons, allowing for particle identification and for a detailed study of the detector response. Digitized analysis of the signals produced in several sensors installed on the same crystal is then a very powerful tool. Superconducting sensors allow to detect the scintillation light pulse followed by the delayed front of phonons, and can be extremely sensitive leading to single photon counting in the visible range. They also provide information on the position of the event inside the absorber, and can be fast enough for all proposed applications. The luminescent bolometer, with superconducting sensors, appears extremely promising for real time $solar$ neutrino experiments based on new indium single crystal scintillators. We focus on this particular application, discussing the status of the art as well as open problems and presenting an updated description of a full scale real time solar neutrino experiment sensitive to the low energy sector. Other applications of the luminescent bolometer (e.g. spectroscopy or neutrino detection at reactors), involving indium compounds and other single crystal scintillators, are equally considered and discussed in detail.
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"abstract": "The luminescent bolometer, proposed in 1988, is now seriously considered for\nseveral applications in nuclear and particle physics: dark matter searches,\ndouble beta decays, low energy neutrino physics, heavy ion physics... It is\nalso a very promising device for basic condensed-matter physics and chemistry\nexperiments, and may lead to astrophysical applications. The luminescent\nbolometer is based on the simultaneous detection of light and phonons, allowing\nfor particle identification and for a detailed study of the detector response.\nDigitized analysis of the signals produced in several sensors installed on the\nsame crystal is then a very powerful tool. Superconducting sensors allow to\ndetect the scintillation light pulse followed by the delayed front of phonons,\nand can be extremely sensitive leading to single photon counting in the visible\nrange. They also provide information on the position of the event inside the\nabsorber, and can be fast enough for all proposed applications. The luminescent\nbolometer, with superconducting sensors, appears extremely promising for real\ntime $solar$ neutrino experiments based on new indium single crystal\nscintillators. We focus on this particular application, discussing the status\nof the art as well as open problems and presenting an updated description of a\nfull scale real time solar neutrino experiment sensitive to the low energy\nsector. Other applications of the luminescent bolometer (e.g. spectroscopy or\nneutrino detection at reactors), involving indium compounds and other single\ncrystal scintillators, are equally considered and discussed in detail.",
"arxiv_id": "physics/9711025",
"authors": [
"Luis Gonzalez-Mestres"
],
"categories": [
"physics.ins-det",
"physics.gen-ph"
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"title": "Luminescent Bolometer and Neutrino Physics",
"url": "https://arxiv.org/abs/physics/9711025"
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