Constraints on invisible B+ K+ X decays from the Belle II B+ K+ measurement

Abstract

Belle II measurement of the branching fraction for B+ K+ shows a 2.7σ excess over the Standard Model prediction and motivates new-physics explanations such as axion-like particles, Higgs-like scalars, or beyond Standard Model gauge bosons. A two-body decay with an invisible X provides a natural candidate explanation. This work provides a comprehensive test of this hypothesis using Belle II's public model-agnostic likelihood. Posterior distributions are derived for the resonance mass mX and the branching fraction, and a modified frequentist upper-limit mass scan is performed. The data favor a resonance with mass mX = 2.1+0.2-0.1 GeV and the product B(B+ K+ X) · PX, inv = 9.2+1.8-3.4 · 10-6, where PX, inv is the probability that X (and its decay products) are undetected. Bayes factors indicate a very strong preference for the Standard Model plus resonance over the Standard Model-only hypothesis. A frequentist likelihood-ratio test favors the Standard Model plus resonance hypothesis by 3.0σ. A light invisible resonance plus the Standard Model therefore provides a compelling description of the Belle II data.