Charge state regulation of nuclear excitation by electron capture in $^{229}$Th ions
Abstract: Nuclear excitation by electron capture (NEEC) in ${229}$Th holds significant potential for precise nuclear state manipulation. In this study, we thoroughly investigate NEEC in ${229}\text{Th}{q+}$ ions by integrating quantum numbers ($n, l, j$) effects and analyzing key parameters (e.g., resonance energy $E_r$, cross section $\sigma$, resonance strength $S$, and NEEC transition width $\Gamma_{\text{NEEC}}$) influences across charge state from $q=1+$ to $90+$. Especially, we focus on the charge-state regulation of the isomeric state (IS, 8.36 eV) and second-excited state (SE, 29.19 keV). Our calculations uncover critical charge-state-dependent behaviors of NEEC in ${229}\text{Th}$ ions: (1) For the IS, valid NEEC channels exhibit threshold migration, where the dominant principal quantum number $n$ increases linearly with $q$ following the relation $n \approx 1.28q + 4.23$; meanwhile, single-$n$-channel $S$ stabilizes between $10{-2}$ to $100$ barn eV via compensatory nucleus-electron coupling, ensuring the total resonance $S$ constant. (2) For the SE, its excitation energy far exceeds nearly all electron binding energies, leading to negligible channel screening and causing the total $S$ to increase monotonically with $q$. This research clarifies the intrinsic mechanisms of charge-state-driven nuclear-electronic interactions in ${229}\text{Th}{q+}$ NEEC and provides a critical reference for future experimental efforts to manipulate ${229}\text{Th}$ nuclear states, particularly via indirect regulation of the SE.
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