Channel couplings in weakly bound nuclear reactions redirect absorbed flux from peripheral loss to inner fusion above the barrier, explaining complete-fusion suppression via an exact identity within the CC/CDCC model.
Exact treatment of continuum couplings in nuclear optical potentials via feshbach theory.arXiv preprint, 2025
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Neural-network ensembles match closed Gaussian systems but lack the open-system non-Hermitian generator and continuous spectrum required by nuclear optical models, yielding a structural negative on applicability.
DPP decomposition in CDCC shows Coulomb bridge dominates peripheral polarization for halo systems like 11Be and 8B, with high-L breakup as signature.
citing papers explorer
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Channel couplings redirect absorbed flux from peripheral loss to fusion in weakly bound nuclear reactions
Channel couplings in weakly bound nuclear reactions redirect absorbed flux from peripheral loss to inner fusion above the barrier, explaining complete-fusion suppression via an exact identity within the CC/CDCC model.
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Integrating Out, Twice:The Open-System Case That Neural-Network Ensemble Theory Is Missing
Neural-network ensembles match closed Gaussian systems but lack the open-system non-Hermitian generator and continuous spectrum required by nuclear optical models, yielding a structural negative on applicability.
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Coulomb bridge mechanism for peripheral polarization of weakly bound projectiles
DPP decomposition in CDCC shows Coulomb bridge dominates peripheral polarization for halo systems like 11Be and 8B, with high-L breakup as signature.