Time-Dependent Precision Measurement of Bs0→ φ μ+μ- Decay at FCC-ee

Abstract

We study the feasibility of measuring time-dependent C\!P violation in the rare flavor-changing neutral current (FCNC) decay Bs0 → φ(→ K+K-) μ+ μ- at the FCC-ee. In the Standard Model (SM), C\!P violation in this mode arises only at higher orders and is highly suppressed. Extensions of the SM, collectively referred to as New Physics (NP), can introduce additional C\!P-violating phases that enhance such effects. The decay Bs0 → φ μ+ μ-, mediated by the b → s + - transition, is therefore a promising probe of NP. The FCC-ee, operating as a high-luminosity Z-factory, offers an optimal environment for this measurement due to its large event yield, clean conditions, efficient particle identification, and excellent vertex resolution. We perform a Monte Carlo study using Pythia and Delphes with the IDEA detector concept. A relative precision better than O(1\%) on the branching ratio and O(10-2) on the time-integrated C\!P asymmetry is found to be achievable. We determine the projected sensitivities to the observables Df, Cf, and Sf, which parameterize time-dependent C\!P violation. In the untagged analysis, a precision of O(10-1) on Df can be reached. With flavor tagging, sensitivities to Cf and Sf improve to O(10-2). These measurements remain inaccessible to current flavor experiments. Interpreting the results within the Weak Effective Theory provides model-independent constraints on C\!P-violating NP. This study demonstrates that FCC-ee enables first-time access to C\!P-sensitive observables previously beyond experimental reach.