β-particle energy-summing correction for β-delayed proton emission measurements

A common approach to studying $\beta$-delayed proton emission is to measure the energy of the emitted proton and corresponding nuclear recoil in a double-sided silicon-strip detector (DSSD) after implanting the $\beta$-delayed proton emitting ($\beta$p) nucleus. However, in order to extract the proton-decay energy, the measured energy must be corrected for the additional energy implanted in the DSSD by the $\beta$-particle emitted from the $\beta$p nucleus, an effect referred to here as $\beta$-summing. We present an approach to determine an accurate correction for $\beta$-summing. Our method relies on the determination of the mean implantation depth of the $\beta$p nucleus within the DSSD by analyzing the shape of the total (proton + recoil + $\beta$) decay energy distribution shape. We validate this approach with other mean implantation depth measurement techniques that take advantage of energy deposition within DSSDs upstream and downstream of the implantation DSSD.