Double Beta Decay of ¹⁰⁰Mo to Excited Final States

A systematic study of the inclusive ($0\nu+2\nu$) double beta ($\beta\beta$) decay of $^{100}$Mo to various excited final states of $^{100}$Ru was performed. Utilizing two large HPGe detectors operated in coincidence, a search for the subsequent deexcitation gamma-gamma cascades was conducted. A 1.05-kg sample of isotopically enriched (98.4%) $^{100}$Mo was investigated for 455 days, yielding an unambiguous observation of the double beta decay of $^{100}$Mo to the $0_1^+$ state (1130.3 keV) of $^{100}$Ru. This excited final state decays via the $0_1^+ \to 2_1^+ \to 0_{gs}^+$ sequence (with $E_{\gamma1}$ = 590.8 keV and $E_{\gamma2}$ = 539.5 keV), and 22 such coincidence events were detected, with a continuous background estimated to be 2.5 events. This counting rate corresponds to a decay half-life for the $\beta\beta($0^+ rightarrow 0_1^+)$ transition of $T_{1/2}^{(0\nu+2\nu)} = [ 6.0^{+1.9}_{-1.1} (\rm{stat}) \pm 0.6(\rm{syst})] \times 10^{20}$ years. Lower limits on decay half-lives were achieved for higher excited final states.