New physics in $B \to K^*\mu\mu$?

TL;DR

Recent anomalies in $B\to K^*\mu\mu$ decays suggest potential new physics contributions, especially affecting the operators $O_9$ and $O_9'$, with implications for TeV-scale models and CP asymmetry measurements.

Contribution

The paper demonstrates that a combined new physics contribution to $O_9$ and $O_9'$ can explain most observed anomalies in $B\to K^*\mu\mu$ decays, linking experimental deviations to specific model implications.

Findings

Anomalies can be explained by new physics in $O_9$ and $O_9'$ operators.

Models with TeV-scale particles can account for the observed deviations.

CP asymmetry measurements could help distinguish among new physics scenarios.

Abstract

Recent experimental results on angular observables in the rare decay $B\to K^*\mu^+\mu^-$ show significant deviations from Standard Model predictions. We investigate the possibility that these deviations are due to new physics. Combining all relevant data on $b \to s$ rare decays, we show that a consistent explanation of most anomalies can be obtained by new physics contributing simultaneously to the semi-leptonic vector operator $O_9$ and its chirality-flipped counterpart $O_9'$. A partial explanation is possible with new physics in $O_9$ or in dipole operators only. We study in detail the implications for models of new physics, in particular the minimal supersymmetric standard model, models with partial compositeness and generic models with flavour-changing $Z^\prime$ bosons. In all considered models, contributions to $B\to K^*\mu^+\mu^-$ of the preferred size imply a spectrum close to the TeV scale. We stress that measurements of CP asymmetries in $B\to K^*\mu^+\mu^-$ could provide valuable information to narrow down possible new physics explanations.