New physics upper bound on the branching ratio of Bs --> l+ l- gamma
Abstract
We consider the effect of new physics on the branching ratio of Bs--> l+ l- gamma where l=e,mu. If the new physics is of the form scalar/pseudoscalar, then it makes no contribution to Bs--> l+ l- gamma, unlike in the case of Bs--> l+ l-, where it can potentially make a very large contribution. If the new physics is in the form of vector/axial-vector operators, then present data on B-->(K,K*)l+ l-, does not allow a large enhancement for Bs--> l+ l- gamma. If the new physics is in the form of tensor/pseudotensor operators, then the data on B-->(K,K*)l+ l- gives no useful constraint but the data on B-->K* gamma does. Here again, a large enhancement of B(Bs--> l+ l- gamma), much beyond the Standard Model expectation, is not possible. Hence, we conclude that the present data on b-->s transitions allow a large boost in Bs--> l+ l- but not in Bs--> l+ l- gamma.
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