$^{159}$Dy electron-capture: a strong new candidate for neutrino mass determination

TL;DR

This study precisely measured the electron-capture $Q$ value of $^{159}$Dy, identifying it as a promising candidate for neutrino mass determination due to an enhanced decay rate near the spectrum endpoint.

Contribution

The paper provides the first high-precision $Q$ value measurement for $^{159}$Dy electron-capture and analyzes its potential for neutrino mass experiments, highlighting the transition to the $5/2^-$ state as particularly promising.

Findings

$^{159}$Dy has the lowest electron-capture $Q$ value among studied isotopes.

Enhanced electron-capture probabilities near the spectrum endpoint for the $5/2^-$ transition.

Transition to the $11/2^+$ state is suppressed and unsuitable for neutrino mass measurement.

Abstract

{ The ground-state to ground-state electron-capture $Q$ value of $^{159}$Dy ($3/2^-$) has been measured directly utilizing the double Penning trap mass spectrometer JYFLTRAP. A value of 364.73(19)~keV was obtained from a measurement of the cyclotron frequency ratio of the decay parent $^{159}$Dy and the decay daughter $^{159}$Tb ions using the novel phase-imaging ion-cyclotron resonance technique. The $Q$ values for allowed Gamow-Teller transition to $5/2^-$ and the third-forbidden unique transition to $11/2^+$ state with excitation energies of 363.5449(14)~keV and 362.050(40)~keV in $^{159}$Tb were determined to be 1.18(19) keV and 2.68(19) keV, respectively. The high-precision $Q$ value of transition $3/2^-\to 5/2^-$ from this work, revealing itself as the lowest electron-capture $Q$ value, is utilized to unambiguously characterise all the possible lines that are present in its electron capture spectrum. { We performed atomic many-body calculations for both transitions to determine electron-capture probabilities from various atomic orbitals, and found an order of magnitude enhancement in the event rates near the end-point of energy spectrum in the transition to the $5/2^-$ nuclear excited state, which can become very interesting once the experimental challenges of identifying decays into excited states are overcome. The transition to the $11/2^+$ state is strongly suppressed and found unsuitable for measuring the neutrino mass. These results show that the electron capture in the $^{159}$Dy atom, going to the $5/2^-$ state of the $^{159}$Tb nucleus, %\textcolor{red} {is a new candidate which may open the way to determine the electron-neutrino mass in the sub-eV region by studying EC. Further experimental feasibility studies, including coincidence measurements with realistic detectors, will be of great interest.} }