External-Field-Assisted Muon Reactivation in Muon-Catalyzed Fusion: A Rate-Network Criterion for Reducing Alpha Sticking

Abstract

Alpha sticking is a major loss channel in deuterium--tritium muon-catalyzed fusion. We study whether an additional external-field-assisted stripping channel can reduce the residual sticking loss after conventional collisional reactivation. The external contribution is written as RX=fXPXηX, where fX is the space--time overlap between the external field and the residual stuck (αμ)+ population, PX is the microscopic stripping probability, and ηX is the probability that the stripped μ- is returned to the dμ/tμ dtμ fusion cycle before escape or decay. This gives ωS eff=ωS0(1-R col)(1-RX) and leads directly to a probability-level no-go condition, ηX crit>1, for any target improvement requiring more recycling than is probabilistically available. We construct an energy-resolved post-stripping rate network including slowing down, atomic capture, free escape, muon decay, atomic-stage loss, ordinary molecular formation, and an effective resonant dtμ channel. Benchmark scans show that the useful regime is a transport window: the stripped muon must be confined and recycled efficiently. With the reference inputs used here, the best-performing scenario increases the cycle yield from N fus,μ=112.6 in the collision-only case to N fus,μ=156.5. Resonant molecular formation suppresses atomic-stage loss and broadens the high-recycling region, but it cannot compensate for prompt escape or poor field--population overlap. The rate network therefore identifies the transport and overlap conditions required for external-field-assisted reactivation to reduce residual alpha sticking.