Isospin-breaking effects of the double-charm molecular pentaquarks
Abstract
We investigate isospin-breaking effects in double-charm molecular pentaquarks with the D(*)c(*) configuration, using the one-boson-exchange potential framework. In these systems, the isospin-breaking effects arise from two sources: the strong interaction, which manifests as the threshold difference of the D(*)c(*) components in the same isospin multiplet and the mass splittings of the exchanged isovector mesons (π and ); and the electromagnetic interaction between charged D(*) and c(*) components. We calculate the binding properties and the isospin mixing angle between the I=1/2 and I=3/2 states of the D(*)c(*) system. Our results show that the isospin-breaking effect contributes a significant correction of roughly 10\%-30\% to the binding energy. This effect is particularly pronounced in loosely bound molecular candidates, which are characterized by small binding energies and large root-mean-square radii. We therefore conclude that the explicit inclusion of isospin-breaking effects is essential for achieving the precision in theoretical calculations necessary to match rapidly advancing experimental programs. Our results are expected to provide valuable guidance for future high-precision experimental studies of deuteron-like molecular states.
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