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Barium Chemosensors with Dry-Phase Fluorescence for Neutrinoless Double Beta Decay

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arxiv 1904.05901 v2 pith:U6NX3NDZ submitted 2019-04-11 physics.ins-det nucl-ex

Barium Chemosensors with Dry-Phase Fluorescence for Neutrinoless Double Beta Decay

classification physics.ins-det nucl-ex
keywords bariumdecaybetadetectiondoublemethodneutrinolesssingle
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The nature of the neutrino is one of the major open questions in experimental nuclear and particle physics. The most sensitive known method to establish the Majorana nature of the neutrino is detection of the ultra-rare process of neutrinoless double beta decay. However, identification of one or a handful of decay events within a large mass of candidate isotope, without obfuscation by backgrounds is a formidable experimental challenge. One hypothetical method for achieving ultra-low-background neutrinoless double beta decay sensitivity is the detection of single $^{136}$Ba ions produced in the decay of $^{136}$Xe (`barium tagging'). To implement such a method, a single-ion-sensitive barium detector must be developed and demonstrated in bulk liquid or dry gaseous xenon. This paper reports on the development of two families of dry-phase barium chemosensor molecules for use in high pressure xenon gas detectors, synthesized specifically for this purpose. One particularly promising candidate, an anthracene substituted aza-18-crown-6 ether, is shown to respond in the dry phase with almost no intrinsic background from the unchelated state, and to be amenable to barium sensing through fluorescence microscopy. This interdisciplinary advance, paired with earlier work demonstrating sensitivity to single barium ions in solution, opens a new path toward single ion detection in high pressure xenon gas.

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