Abstract
We consider a gauge-invariant, mass-independent prescription for renormalizing composite operators, regularized on the lattice, in the spirit of the coordinate space (X-space) renormalization scheme. The prescription involves only Green's functions of products of gauge-invariant operators, situated at distinct space-time points, in a way as to avoid potential contact singularities. Such Green's functions can be computed nonperturbatively in numerical simulations, with no need to fix a gauge: thus, renormalization to this "intermediate" scheme can be carried out in a completely nonperturbative manner. Expressing renormalized operators in the $\overline{\rm MS}$ scheme requires the calculation of corresponding conversion factors. The latter can only be computed in perturbation theory, by the very nature of the $\overline{\rm MS}$; however, the computations are greatly simplified by virtue of the following attributes: i) In the absense of operator mixing, they involve only massless, two-point functions; such quantities are calculable to very high perturbative order. ii) They are gauge invariant; thus, they may be computed in a convenient gauge. iii) Where operator mixing may occur, only gauge-invariant operators will appear in the mixing pattern: Unlike other schemes, involving mixing with gauge-variant operators (which may contain ghost fields), the mixing matrices in the present scheme are greatly reduced. Still, computation of some three-point functions may not be altogether avoidable. We exemplify the procedure by computing, to lowest order, the conversion factors for fermion bilinear operators of the form $\bar\psi\Gamma\psi$ in QCD. We also employ the gauge-invariant scheme in the study of mixing between gluon and quark energy-momentum tensor operators: We compute to one loop the conversion factors relating the nonperturbative mixing matrix to the $\overline{\rm MS}$ scheme.
Highlights
The latter can only be computed in perturbation theory, by the very nature of minimal subtraction (MS); the computations are greatly simplified by virtue of the following attributes: (i) In the absence of operator mixing, they involve only massless, two-point functions; such quantities are calculable to very high perturbative order. (ii) They are gauge invariant; they may be computed in a convenient gauge. (iii) Where operator mixing may occur, only gauge-invariant operators will appear in the mixing pattern: unlike other schemes, involving mixing with gauge-variant operators, the mixing matrices in the present scheme are greatly reduced; still, computation of some three-point functions may not be altogether avoidable
In the second part of our work, we extend the application of GIRS in the presence of mixing: we study the renormalization and mixing of the gluon and quark parts of the QCD energy-momentum tensor (EMT); this is a subject of research with an increased interest in recent years [20,21,22,23,24]
We study a gauge-invariant, mass-independent renormalization scheme (GIRS) for composite operators, which is applicable in both perturbative and nonperturbative studies
Summary
A number of candidate GFs can be employed for this purpose, such as hOμi νðxÞO1ðyÞO1ðzÞi, where Oμi ν is the gluon or quark energy-momentum tensor operator and O1ðxÞ 1⁄4 ψðxÞψðxÞ is the scalar bilinear operator; we compute the corresponding conversion factors for some of the most prominent candidates The applicability of both RI0 and GIRS relies on the existence of a window: 1⁄2a; Λ−Q1CD (where a is the lattice spacing and ΛQCD is the QCD physical scale), which must be wide enough in order to keep lattice artifacts under control and to ensure the reliability of perturbation theory. III is devoted to the renormalization and mixing of the quark and gluon EMT operators In both sections, we provide details on the calculational procedure and we present our tree-level and one-loop results for the bare GFs of operators under study, as well as for the conversion factors between GIRS and MS schemes.
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