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arxiv: 2501.06029 · v1 · pith:HGVKD5I7new · submitted 2025-01-10 · ⚛️ nucl-ex · astro-ph.SR· physics.ins-det

Bound-State Beta Decay of mathbf{mathrm{²⁰⁵{Tl}⁸¹⁺}} Ions and the LOREX Project

classification ⚛️ nucl-ex astro-ph.SRphysics.ins-det
keywords betadecayionslorexmathrmbound-statehalf-lifelorandite
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Stable $^{205}$Tl ions have the lowest known energy threshold for capturing electron neutrinos ($\nu_e$) of ${ E}_{\nu_e}\ge50.6$\,keV. The Lorandite Experiment (LOREX), proposed in the 1980s, aims at obtaining the longtime averaged solar neutrino flux by utilizing natural deposits of Tl-bearing lorandite ores. To determine the $\nu_e$ capture cross section, it is required to know the strength of the weak transition connecting the ground state of $^{205}$Tl and the 2.3 keV first excited state in $^{205}$Pb. The only way to experimentally address this transition is to measure the bound-state beta decay ($\beta_{b}$) of fully ionized $\mathrm{^{205}Tl^{81+}}$ ions. After three decades of meticulous preparation, the half-life of the $\beta_{b}$ decay of $\mathrm{^{205}Tl^{81+}}$ has been measured to be $291_{-27}^{+33}$ days using the Experimental Storage Ring (ESR) at GSI, Darmstadt. The longer measured half-life compared to theoretical estimates reduces the expected signal-to-noise ratio in the LOREX, thus challenging its feasibility.

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