Charge state regulation of nuclear excitation by electron capture in 229Th ions

Abstract

Nuclear excitation by electron capture (NEEC) in 229Th holds significant potential for precise nuclear state manipulation. In this study, we thoroughly investigate NEEC in 229Thq+ ions by integrating quantum numbers (n, l, j) effects and analyzing key parameters (e.g., resonance energy Er, cross section σ, resonance strength S, and NEEC transition width 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 229Th 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 ≈ 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 229Thq+ NEEC and provides a critical reference for future experimental efforts to manipulate 229Th nuclear states, particularly via indirect regulation of the SE.

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