Shell model calculations discover a low-energy M1 radiation spike (LEMAR) from proton-neutron high-j orbital recoupling that boosts r-process reaction rates by a factor of 2.5 in A≈132 nuclei and follows Planck's law.
Low-energy magnetic radiation: deviations from GOE
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abstract
A pronounced spike at low energy in the strength function for magnetic radiation (LEMAR) is found by means of Shell Model calculations, which explains the experimentally observed enhancement of the dipole strength. LEMAR originates from statistical low-energy M1-transitions between many excited complex states. Re-coupling of the proton and neutron high-j orbitals generates the strong magnetic radiation. LEMAR is closely related to Magnetic Rotation. LEMAR is predicted for nuclides participating in the r-process of element synthesis and is expected to change the reaction rates. An exponential decrease of the strength function and a power law for the size distribution of the $B(M1)$ values are found, which strongly deviate from the ones of the GOE of random matrices, which is commonly used to represent complex compound states.
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Low-Energy Magnetic Radiation
Shell model calculations discover a low-energy M1 radiation spike (LEMAR) from proton-neutron high-j orbital recoupling that boosts r-process reaction rates by a factor of 2.5 in A≈132 nuclei and follows Planck's law.