Identifying a $Z'$ behind $b \to s \ell \ell$ anomalies at the LHC
arXiv:1803.07492 · doi:10.1103/PhysRevD.97.115019
Abstract
Recent $b\to s\ell\ell$ anomalies may imply the existence of a new $Z'$ boson with left-handed $Z'bs$ and $Z'μμ$ couplings. Such a $Z'$ may be directly observed at LHC via $b \bar s \to Z' \to μ^+μ^-$, and its relevance to $b\to s\ell\ell$ may be studied by searching for the process $gs \to Z'b \to μ^+μ^- b$. In this paper, we analyze the capability of the 14 TeV LHC to observe the $Z'$ in the $μ^+ μ^-$ and $μ^+μ^- b$ modes based on an effective model with major phenomenological constraints imposed. We find that both modes can be discovered with 3000 fb$^{-1}$ data if the $Z'bs$ coupling saturates the latest $B_s-\bar B_s$ mixing limit from UTfit at around $2Ï$. Besides, a tiny right-handed $Z'bs$ coupling, if it exists, opens up the possibility of a relatively large left-handed counterpart, due to cancellation in the $B_s-\bar B_s$ mixing amplitude. In this case, we show that even a data sample of $\mathcal{O}(100)$ fb$^{-1}$ would enable discovery of both modes. We further study the impact of a $Z'bb$ coupling as large as the $Z'bs$ coupling. This scenario enables discovery of the $Z'$ in both modes with milder effects on the $B_s-\bar B_s$ mixing, but obscures the relevance of the $Z'$ to $b \to s\ell\ell$. Discrimination between the $Z'bs$ and $Z'bb$ couplings may come from the production cross section for the $Z'b\bar{b}$ final state. However, we do not find the prospect for this to be promising.
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