Abstract
The \(\bar{B}\rightarrow X_s\gamma \) branching ratio is currently measured with around \(5\%\) accuracy. Further improvement is expected from Belle II. To match such a precision on the theoretical side, evaluation of \({\mathcal O}(\alpha _{\mathrm s}^2)\) corrections to the partonic decay \(b \rightarrow X_s^\textrm{part}\gamma \) are necessary, which includes the \(b \rightarrow s \gamma \), \(b \rightarrow s g\gamma \), \(b \rightarrow s gg\gamma \), \(b \rightarrow sq\bar{q}\gamma \) decay channels. Here, we evaluate the unrenormalized contribution to \(b \rightarrow s \gamma \) that stems from the interference of the photonic dipole operator \(Q_7\) and the current–current operators \(Q_1\) and \(Q_2\). Our results, obtained in the cut propagator approach at the 4-loop level, agree with those found in parallel by Fael et al. who have applied the amplitude approach at the 3-loop level. Partial results for the same quantities recently determined by Greub et al. agree with our findings, too.
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1 Introduction
Rare B-meson decays that receive their leading Standard Model (SM) contributions from one-loop diagrams provide important constraints on popular Beyond Standard Model (BSM) scenarios. Among them, the inclusive radiative decay \(\bar{B}\rightarrow X_s\gamma \) is of particular interest. Its isospin- and \({\mathrm CP}\)-averaged branching ratio has been measured by CLEO [1], Belle [2, 3], BABAR [4,5,6], and Belle II [7] for \(E_\gamma > E_0\) in the decaying meson rest frame, with various values of \(E_0\), ranging from \(1.7\,\textrm{GeV}\) to \(2.0\,\textrm{GeV}\). The current world average of these measurementsFootnote 1 extrapolated to \(E_0 = 1.6\,\textrm{GeV}\) reads [8, 9]
An extrapolation in \(E_0\) has been applied because measurements are less precise for lower values of \(E_0\) due to a rapidly growing background – see, e.g., Fig. 2 in Ref. [7]. On the other hand, theoretical estimates of non-perturbative effects are less precise for higher values of \(E_0\) – see Refs. [10, 11] for the most recent analyses of this issue.
At \(E_0 = 1.6\,\textrm{GeV}\), the \(\bar{B}\rightarrow X_s\gamma \) decay rate is well approximated by the corresponding perturbative \(b \rightarrow X_s^p\gamma \) decay rate, where \(X_s^p = s,sg,sgg,sq\bar{q},\ldots \) are the partonic final states. The most relevant non-perturbative corrections to this approximation are suppressed by powers of \((m_B-m_b)/m_b\). The largest non-perturbative contribution to the overall uncertainty arises from the so-called resolved photon effects that have been extensively studied in Refs. [12,13,14,15,16].
As far as the dominant perturbative contributions are concerned, they need to be evaluated including Next-to-Leading Order (NLO) electroweak and Next-to-Next-to-Leading Order (NNLO) QCD corrections to match the experimental accuracy. Some of the important NNLO QCD (\({\mathcal O}(\alpha _{\mathrm s}^2)\)) corrections that depend on the charm quark mass \(m_c\) have been calculated only in the limits \(m_c=0\) [17] and \(m_c \gg m_b\) [18]. An interpolation between the two limits was then applied [17]. The resulting SM prediction obtained in 2015 [19] was subsequently updated in 2020 [20] to yield
where the overall uncertainty contains \(\pm 3\%\) from the \(m_c\)-interpolation, \(\pm 3\%\) from unknown higher-order effects, and \(\pm 2.5\%\) from the input parameters (combined in quadrature), which includes the non-perturbative uncertainties. The resolved photon contributions are treated along the lines of Ref. [13] – see Ref. [20] for details.
While the results in Eqs. (1.1) and (1.2) are in perfect agreement, further improvement on both the experimental and theoretical sides are expected. The ultimate Belle II luminosity will allow for high-statistics measurements using the hadronic tag method for the recoiling B meson, which efficiently suppresses the non-\(B\bar{B}\) backgrounds [21] and makes the determination of \(E_\gamma \) in the decaying B-meson rest frame possible on an event-by-event basis [4, 7]. As far as the perturbative calculations are concerned, most effort is being devoted to eliminating the \(m_c\)-interpolation at \({\mathcal O}(\alpha _{\mathrm s}^2)\) by evaluation of the corresponding corrections at the physical value of \(m_c\).
In this paper, we present results of our calculation of the unrenormalized \(m_c\)-dependent NNLO QCD corrections to the \(b \rightarrow s\gamma \) decay rate at the physical value of \(m_c\). They need to be supplemented in the future with the corresponding bremsstrahlung contributions (with \(X_s^p = sg,sgg,sq\bar{q}\)), for which our calculations are advanced but not yet finished. However, the observed agreement with the parallel calculation of Ref. [22], as well as the published partial results of Ref. [23] makes us confident that the two-body-final-state contributions in our calculation can be treated as cross-checked, and are ready for publication.
The article is organized as follows. In the next section, we provide the necessary definitions to specify the corrections we actually calculate. Next, our method for the evaluation of 4-loop propagator diagrams with unitarity cuts is briefly described. In Sect. 3, our final results for the corrections considered are presented for a sample physical value of \(z = m_c^2/m_b^2\), namely \(z=0.04\). We conclude in Sect. 4.
2 Details of the calculation
We work in the framework of an effective theory that is obtained from the SM via the decoupling of the W boson and all heavier particles. The flavour-changing weak interaction terms that affect the \(b \rightarrow s \gamma \) transition take then the formFootnote 2
The \(\overline{\textrm{MS}}\)-renormalized Wilson coefficients \(C_i(\mu _b)\) are already known up to NNLO in QCD at the renormalization scale \(\mu _b \sim m_b\). Explicit expressions for the operators \(Q_i\) can be found, e.g., in Eq. (1.6) of Ref. [17].Footnote 3 For our present purpose, only three of them matter, namely
The weak radiative b-quark decay rate can be written as
where the quantities \(\hat{G}_{ij}\) depend on the photon energy cut \(E_0\), the renormalization scale \(\mu _b\), and the ratio \(z = m_c^2/m_b^2\) of the charm and bottom quark masses.Footnote 4 Their perturbative expansion in \(\alpha _{\mathrm s}\) reads
Currently, the dominant uncertainty in Eq. (2.3) arises from the z-dependence of \(\hat{G}_{17}^{(2)}\) and \(\hat{G}_{27}^{(2)}\). These are the very quantities for which the interpolation mentioned in the Introduction has been applied. In the following discussion, we refer only to \(\hat{G}_{27}^{(2)}\), for brevity. The calculation of \(\hat{G}_{17}^{(2)}\) has been performed alongside – it differs by colour factors only. We shall present both results in Sect. 3.
Let us split the unrenormalized (bare) interference term \(\hat{G}_{27}^{(2)\mathrm bare}\) into contributions from two-, three- and four-particle final states
The two-particle contribution \(\hat{G}_{27}^{(2)2P}\) can be further split into a sum of two types of interference
where each \(\Delta _{kn}\) picks the interference of a k-loop amplitude with the insertion of \(Q_2\), and an n-loop amplitude with the insertion of \(Q_7\). There are only two terms in Eq. (2.6) because the one-loop \(b \rightarrow s \gamma \) matrix element of \(Q_2\) turns out to vanish.
In the next section, we will present separate results for \(\Delta _{30} \hat{G}_{27}^{(2)2P}\) and \(\Delta _{21} \hat{G}_{27}^{(2)2P}\). The former can be calculated in two ways. One is to compute the three-loop \(b \rightarrow s \gamma \) matrix element of \(Q_2\), and multiply its real partFootnote 5 by the (real) tree-level matrix element of \(Q_7\). Such an “amplitude” approach was applied in Ref. [22]. Partial results for \(\Delta _{30} \hat{G}_{27}^{(2)2P}\) in Ref. [23] were also obtained using the same method.
Here, we apply the cut propagator approach, as in Ref. [17] in the \(m_c=0\) case. It requires essentially the same effort as the amplitude approach in the case of two-particle final states, but is likely more convenient for higher-multiplicity final states. Following the well-known procedure [26], we express the phase-space integrals in terms of regular loop integrals but with cut propagators, using the identity
Once this is done, the usual Integration-By-Parts (IBP) algorithms can be used to express the quantities in question in terms of Master Integrals (MIs). The same algorithms are applied to derive Differential Equations (DEs) for the MIs, which is essential for their efficient evaluation.
Sample four-loop propagator diagrams that contribute to \(\hat{G}_{27}^{(2)2P}\) in our approach are presented in Fig. 1. Let us note that there exist physical cuts in some of these diagrams that do not go through the photon line, and therefore should not be included. This means that we neither take the imaginary part of the whole four-loop propagator, nor take advantage of the optical theorem.
We generate the necessary diagrams with the help of QGRAF [27] and/or FeynArts [28, 29] supplemented with self-written codes. The Feynman–’t Hooft gauge fixing (\(\xi =1\)) is used. No diagrams with loop corrections on external (or cut) lines are included, which matches the conventions of the corresponding counterterm contributions in Eq. (2.1) of Ref. [30]. We skip the diagrams where no gluon connects the charm loop (with the \(Q_2\) vertex) to the rest of the diagram. Such diagrams contain subdiagrams that either vanish or sum up to zero. We also skip the diagrams with ghost or gluon one-loop corrections on the gluon lines. Their effects are read out from the corresponding massless quark loops, and included in our results in the next section. Eventually, we are left with 198 four-loop propagator diagrams that need to be calculated.
In each of the Feynman integrands, we average over the external b-quark polarizations, and evaluate the necessary Dirac traces with the help of FORM [31]. Next, once all the Lorentz indices have been contracted, the full \(\hat{G}_{27}^{(2)2P}\) becomes a linear combination of scalar integrals. Their reduction to MIs is performed with the help of Kira [32, 33] that generates and applies the IBP identities. Altogether, 447 MIs are found to be independent.
The calculation of MIs is performed with the help of AMFlow [34]. An artificial imaginary mass-squared parameter \(\eta \) is introduced in each denominator, and the IBP method is used to derive DEs in \(\eta \) for the MIs. Next, the DEs are numerically solved with initial conditions at very large \(|\eta |\). All the physical mass ratios and dimensionless kinematic invariants are assigned fixed numerical values to facilitate the IBP reduction.
3 Results
In our case, the only physical mass ratio involved is \(z = m_c^2/m_b^2\). No kinematic invariants are present, as we deal with a massive particle decaying to two massless particles. To fix the numerical value of z, we follow the convention of Ref. [17] where \(z = m_c^{\overline{\textrm{MS}}}(\mu _c)/m_{b,\textrm{kin}}\) was used in lower-order contributions, where \(m_{b,\textrm{kin}} \simeq 4.564\,\textrm{GeV}\) denotes the b-quark mass in the kinetic scheme at \(\mu _\textrm{kin} = 1\,\textrm{GeV}\). Below, we present our final results for \(z=0.04\) which corresponds to \(\mu _c \simeq m_b(m_b) \simeq 4.2\,\textrm{GeV}\).
Our expressions for \(\Delta _{30} \hat{G}^{(2)2P}_{27}\) and \(\Delta _{30} \hat{G}^{(2)2P}_{17}\) at \(z=0.04\) read
where all the numerical coefficients have been truncated at the sixth decimal place.
As far as \(\Delta _{21} \hat{G}^{(2)2P}_{27}\) and \(\Delta _{21} \hat{G}^{(2)2P}_{17}\) are concerned, we find
where \(p(z=0.04) \simeq 144.959811\). The large-z expansion of p(z) reads
with \(L=\log z\). The NLO functions \(f_0(z)\) and \(f_1(z)\) are defined through
Their expansions around \(z=0\) were originally found in Refs. [30, 35], respectively. Fully analytical expressions for them in terms of harmonic polylogarithms have been recently determined in Ref. [22]. Their numerical values at \(z=0.04\) are \(f_0(z=0.04) \simeq -6.371045\) and \(f_1(z=0.04) \simeq -18.545805\).
Contributions from diagrams with quark loops on the gluon lines are present in Eq. (3.1) only. They are marked with \(n_b=1\) (bottom loops), \(n_c=1\) (charm loops), and \(n_l=3\) (light quark loops). The main new results of the current paper are the remaining contributions that stem from diagrams with no quark loops on the gluon lines.
In the case of Eq. (3.1), we find perfect agreement with the results of Ref. [22], after taking into account their global normalization convention (see Eq. (10) there). To perform the comparison, we have relied on the supplementary material to that paper where deep expansions around \(z=0\) of their quantities \(t_2\) and \(t_3\) are given. We can also confirm the partial results of Ref. [23], once we restrict to their subset of diagrams.
In the case of our Eq. (3.2), analytical expressions for all the \(\frac{1}{\epsilon ^n}\) poles have been extracted from the former NLO QCD calculations of the \(\langle s\gamma |Q_2|b\rangle _\mathrm{2\;loop}\) and \(\langle s\gamma |Q_7|b\rangle _\mathrm{1\;loop}\) [36] matrix elements. They are in full agreement with our current numerical results. As far as the finite contribution p(z) is concerned, it is determined for the first time here. It cannot be extracted from the NLO results because dimensionally regulated infrared (IR) divergences in \(\langle s\gamma |Q_7|b\rangle _\mathrm{1\;loop}\) make the so-far-unknown higher-order terms in the \(\epsilon \)-expansion of \(\langle s\gamma |Q_2|b\rangle _\mathrm{2\;loop}\) relevant. The IR divergences will cancel only after taking into account the yet uncalculated NNLO contributions from diagrams with 3- and 4-body cuts.
4 Summary and outlook
We evaluated the unrenormalized corrections \(\hat{G}^{(2)2P}_{17}\) and \(\hat{G}^{(2)2P}_{27}\) to the perturbative \(b \rightarrow s \gamma \) decay rate. In the future, these need to be supplemented with contributions from three- and four-body final states to get rid of IR divergences. Then they can be renormalized using counterterm contributions in Eq. (2.1) of Ref. [30] where all the necessary counterterm ingredients were calculated. We have already tested such a renormalization in our expansions around the large-\(m_c\) limit which provide the initial conditions required to solve the DEs in z. The highest poles (\(\frac{1}{\epsilon ^3}\) and \(\frac{1}{\epsilon ^2}\)) are properly cancelled. However, a missing piece with a \(\frac{1}{\epsilon }\) divergence in the three- and four-body bare contributions was identified, and is currently being evaluated.
Given that the complete (partial) results for \(\Delta _{30} \hat{G}^{(2)2P}_{17}\) and \(\Delta _{30} \hat{G}^{(2)2P}_{27}\) in Refs. [22, 23] agree with our findings, we have decided to present them now, and supplement with \(\Delta _{21} \hat{G}^{(2)2P}_{17}\) and \(\Delta _{21} \hat{G}^{(2)2P}_{27}\), even though no physical conclusion can be drawn from unrenormalized results alone. Given the complexity of the necessary calculations and the phenomenological relevance of the expected ultimate result, presenting intermediate results allows for valuable cross-checks and provides a boost for reaching the final goal.
Our results in the previous section have been presented only for a single value of z. In the case of \(\Delta _{30} \hat{G}^{(2)2P}_{17}\) and \(\Delta _{30} \hat{G}^{(2)2P}_{27}\), an exhaustive analysis of z-dependence can be found in Ref. [22]. As far as the remaining contributions are concerned, we will study their dependence on z only at the level of the fully inclusive and renormalized results for \(\hat{G}^{(2)}_{17}\) and \(\hat{G}^{(2)}_{27}\).
Data Availability
This manuscript has no associated data or the data will not be deposited. [Authors’ comment: This is a theoretical study and no experimental data has been listed.]
Notes
Terms that contribute beyond the leading order in electroweak interactions and/or are suppressed by the small Cabibbo–Kobayashi–Maskawa matrix element \(V_{ub}\) will be omitted here, as we focus on \({\mathcal O}(\alpha _{\mathrm s}^2)\) effects.
We shall strictly follow the notation of Ref. [17] throughout the current paper.
The light u, d and s quark masses are set to zero in \({\mathcal O}(\alpha _{\mathrm s}^2)\) interference terms involving the operator \(Q_7\) which we are interested in here. However, they need to be retained in numerically subleading terms to get rid of collinear divergences – see, e.g., Refs. [24, 25].
The imaginary part would matter only for the \({\mathcal O}(V_{ub})\) correction that we neglect at the \({\mathcal O}(\alpha _{\mathrm s}^2)\) level. Such an effect drops out after CP-averaging anyway.
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Acknowledgements
The research of M. Czakon, T. Huber, M. Niggetiedt (partially) and M. Steinhauser was supported by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) under grant 396021762 – TRR 257 “Particle Physics Phenomenology after the Higgs Discovery”. M. Czaja and M. Misiak acknowledge partial support by the National Science Center, Poland, under the research project 2020/37/B/ST2/02746. K. Schönwald was supported by the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme grant agreement 101019620 (ERC Advanced Grant TOPUP). M. Niggetiedt was partially supported by the Deutsche Forschungsgemeinschaft (DFG) under grant 400140256 - GRK 2497: “The physics of the heaviest particles at the Large Hardon Collider.” The work of A. Rehman was supported by NSERC grant SAPIN-2022-00020.
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Czaja, M., Czakon, M., Huber, T. et al. The \(Q_{1,2}\)–\(Q_7\) interference contributions to \(b \rightarrow s \gamma \) at \({\mathcal O}(\alpha _{\mathrm s}^2)\) for the physical value of \(m_c\). Eur. Phys. J. C 83, 1108 (2023). https://doi.org/10.1140/epjc/s10052-023-12270-8
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DOI: https://doi.org/10.1140/epjc/s10052-023-12270-8