Renormalization and Factorization Scale-Invariant Predictions for the Higgs Rare Decay H J/+γ via the Principle of Maximum Conformality

Abstract

We investigate the \(J/\) direct production mechanism in the rare exclusive Higgs decay \(H J/+γ\) within nonrelativistic QCD (NRQCD), which provides a clean probe for extracting the charm-quark Yukawa coupling to the Higgs boson. The Principle of Maximum Conformality (PMC) is used to remove conventional renormalization-scheme and scale ambiguities in the next-to-next-to-leading-order (N\(2\)LO) perturbative QCD series. Large logarithmic contributions arising from Yukawa coupling renormalization are resummed, providing a reliable foundation for subsequent analyses. Using the experimentally measured leptonic decay width of \(J/\) and the N\(2\)LO perturbative result, we extract the factorization-scale-dependent long-distance matrix element \( J/( ε)| σ· ε(μ) |0\). Combining this with the factorization-scale-dependent short-distance coefficient, we obtain a factorization-scale-invariant decay width for the channel. Compared with earlier predictions in the literature, our fixed-order result for \((H J/+γ)\) is more robust and precise, with good convergence and no renormalization- or factorization-scale dependence. We find \((H J/+γ) = (6.4574+0.3995-0.3995) × 10-11\) GeV, where the uncertainty is the quadratic sum of contributions from \(αs(mZ) = 0.0009\), \(J/ e+e- = 0.10\ GeV\), \(mc(mc) = 0.0046\ GeV\), and the estimated magnitude of N\(3\)LO contributions from Bayesian analysis. This work demonstrates for the first time how the PMC can be applied to obtain fixed-order perturbative predictions that are invariant under both renormalization and factorization scale variations.

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