NNLO QCD Corrections to D-Wave Spin-Singlet Heavy Quarkonia Decay ηQ2γγ via the Principle of Maximum Conformality

Abstract

In this paper, we perform a comprehensive study of the decay process ηQ2γγ for D-wave spin-singlet heavy quarkonia up to next-to-next-to-leading-order (NNLO) QCD corrections within the nonrelativistic QCD effective theory. Following its factorization formalism, the total decay width is decomposed into perturbatively calculable short-distance coefficients (SDCs) and nonperturbative D-wave long-distance matrix elements (LDMEs). The original NNLO series of SDCs suffers from sizable renormalization and factorization scale uncertainties. To eliminate such inherent scale ambiguities, we adopt the Principle of Maximum Conformality (PMC). We show that recursively applying the renormalization group equations for the running of αs and D-wave LDMEs within the PMC framework yields an effective strong coupling αs(Q) consistent with the expansion coefficients, resulting in a scale-invariant perturbative series. The determined PMC scales are Q=1.483 GeV for ηc2 and Q=4.246 GeV for ηb2. By removing divergent renormalon contributions, the PMC naturally improves the convergence of the perturbative series for SDCs. Our PMC predictions for the total decay widths are Γηc2γγ PMC = 3.322+0.899-0.828\ eV and Γηb2γγ PMC = 0.0188+0.0014-0.0013\ eV. The uncertainties arise from variations of the charm and bottom quark masses Δmc= 0.07 GeV, Δmb= 0.06 GeV, as well as systematic errors from uncalculated higher-order corrections. The corresponding branching ratios are Br(ηc2γγ) = (7.463+2.020-1.860)× 10-6 and Br(ηb2γγ) = (6.460+0.481-0.447)× 10-7.