A shell-model variant exploiting the energy-localized Brink-Axel hypothesis computes electric and magnetic radiative strength functions across relevant energies, with benchmarks on 24Mg and new findings for 56Fe on M1 smoothness and incomplete low-energy strength reproduction.
TALYS: modeling of nuclear reactions
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New cross sections for natC(n,p) and natC(n,d) up to 25 MeV are higher than evaluations and agree with TALYS-2.0 after model-assisted corrections for excited states.
Reports an experimental measurement of 19,20O(p,n)19,20F reactions in inverse kinematics with the MuSIC@Indiana active target, enabling extraction of the proton fusion cross section via background rejection.
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Radiative strength functions from the energy-localized Brink-Axel hypothesis
A shell-model variant exploiting the energy-localized Brink-Axel hypothesis computes electric and magnetic radiative strength functions across relevant energies, with benchmarks on 24Mg and new findings for 56Fe on M1 smoothness and incomplete low-energy strength reproduction.
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Energy-differential measurement of the $^{\mathrm{nat}}$C(n,p) and $^{\mathrm{nat}}$C(n,d) reactions at the n_TOF facility at CERN
New cross sections for natC(n,p) and natC(n,d) up to 25 MeV are higher than evaluations and agree with TALYS-2.0 after model-assisted corrections for excited states.
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Measuring $^{19,20}$O(p,n)$^{19,20}$F reactions using an active target detector
Reports an experimental measurement of 19,20O(p,n)19,20F reactions in inverse kinematics with the MuSIC@Indiana active target, enabling extraction of the proton fusion cross section via background rejection.