New physics in $b \to s e^+ e^-$?
Abstract
At present, the measurements of some observables in and decays, and of , are in disagreement with the predictions of the standard model. While most of these discrepancies can be removed with the addition of new physics (NP) in , a difference of still remains in the measurement of at small values of , the dilepton invariant mass-squared. In the context of a global fit, this is not a problem. However, it does raise the question: if the true value of is near its measured value, what is required to explain it? In this paper, we show that, if one includes NP in , one can generate values for that are within of its measured value. Using a model-independent, effective-field-theory approach, we construct many different possible NP scenarios. We also examine specific models containing leptoquarks or a gauge boson. Here, additional constraints from lepton-flavour-violating observables, - mixing and neutrino trident production must be taken into account, but we still find a number of viable NP scenarios. For the various scenarios, we examine the predictions for in other bins, as well as for the observable .
Cite
@article{arxiv.1901.04516,
title = {New physics in $b \to s e^+ e^-$?},
author = {Jacky Kumar and David London},
journal= {arXiv preprint arXiv:1901.04516},
year = {2019}
}
Comments
16 pages, 1 figure. We have added constraints from lepton-flavour-violating observables. These eliminate the scenario with only the $U_1$ leptoquark. All other scenarios are unchanged. Apr. 12: some text and references added, in particular a "Note added" regarding the new results reported at Moriond 2019