Quark-gluon vertex: A perturbation theory primer and beyond

Bermudez, Rocio; Albino, Luis; Gutiérrez-Guerrero, L. X.; Tejeda-Yeomans, María Elena; Bashir, Adnan

doi:10.1103/physrevd.95.034041

Cited by 58 publications

(54 citation statements)

References 88 publications

(130 reference statements)

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“…Our result differs significantly from the perturbative estimation of the form factors [5], where all the strength appears associated to λ 1 . For example, for the kinematical configuration defined by p 2 = (p − q) 2 at vanishing p they have The comparison of our results with those reported in [17,22,23] is difficult to perform but in these works λ 1 clearly dominates.…”

Section: The Quark-gluon Vertex Form Factorscontrasting

confidence: 99%

“…Despite its relevance for strong interactions, a e-mail: orlando@uc.pt b e-mail: wayne@ita.br c e-mail: tobias@ita.br d e-mail: joao.mello@cruzeirodosul.edu.br our knowledge of the quark-gluon vertex from first principles calculations is relatively poor. At the perturbative level, only recently a full calculation of the twelve form factors associated to this vertex was published [5] but only for some kinematical configurations, namely the symmetric configuration (equal incoming, outgoing quark and gluon squared momenta), the on-shell configuration (quarks on-shell with vanishing gluon momentum) and what the authors called its asymptotic limit. In particular, the vertex asymptotic limit was used to investigate ansätze that can be found in the literature [6][7][8][9][10][11] with the aim to test their description of the ultraviolet regime.…”

Section: Introductionmentioning

confidence: 99%

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The quark-gluon vertex and the QCD infrared dynamics

et al. 2019

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The Dyson-Schwinger quark equation is solved for the quark-gluon vertex using the most recent lattice data available in the Landau gauge for the quark, gluon and ghost propagators, the full set of longitudinal tensor structures in the Ball-Chiu vertex, taking into account a recently derived normalisation for a quark-ghost kernel form factors and the gluon contribution for the tree level quark-gluon vertex identified on a recent study of the lattice soft gluon limit. A solution for the inverse problem is computed after the Tikhonov linear regularisation of the integral equation, that implies solving a modified Dyson-Schwinger equation. We get longitudinal form factors that are strongly enhanced at the infrared region, deviate significantly from the tree level results for quark and gluon momentum below 2 GeV and at higher momentum approach their perturbative values. The computed quark-gluon vertex favours kinematical configurations where the quark momentum p and the gluon momentum q are small and parallel. Further, the quark-gluon vertex is dominated by the form factors associated to the tree level vertex γ µ and to the operator 2 p µ + q µ . The higher rank tensor structures provide small contributions to the vertex.

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Section: The Quark-gluon Vertex Form Factorscontrasting

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The quark-gluon vertex and the QCD infrared dynamics

et al. 2019

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“…The modification, proposed in Ref. [60] guarantees that the corresponding form factors are free of kinematic singularities in all covariant gauges [46,60]. In addition, this basis also permits one to establish a more transparent relation between the ST and the transverse parts of the vertex.…”

Section: General Frameworkmentioning

confidence: 99%

Non-Abelian Ball-Chiu vertex for arbitrary Euclidean momenta

Aguilar¹,

Cardona²,

Ferreira³

et al. 2017

Phys. Rev. D

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We determine the non-Abelian version of the four non-transverse form factors of the quark-gluon vertex, using exact expressions derived from the Slavnov-Taylor identity that this vertex satisfies.In addition to the quark and ghost propagators, a key ingredient of the present approach is the quark-ghost scattering kernel, which is computed within the one-loop dressed approximation. The vertex form factors obtained from this procedure are evaluated for arbitrary Euclidean momenta, and display features not captured by the well-known Ball-Chiu vertex, deduced from the Abelian (ghost-free) Ward identity. Particularly interesting in this analysis is the so-called soft gluon limit, which, unlike other kinematic configurations considered, is especially sensitive to the approximations employed for the vertex entering in the quark-ghost scattering kernel, and may even be affected by a subtle numerical instability. As an elementary application of the results obtained, we evaluate and compare certain renormalization-point-independent combinations, which contribute to the interaction kernels appearing in the standard quark gap and Bethe-Salpeter equations. In doing so, even though all form factors of the quark-gluon vertex, and in particular the transverse ones which are unconstrained by our procedure, enter non-trivially in the aforementioned kernels, only the contribution of a single form factor, corresponding to the classical (tree-level) tensor, will be considered.

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“…The motivation for this choice is that one expects singularities at timelike momentain in the quark-gluon kernel, coming either from the gluon propagator or from the quark-gluon vertex, or from both. Certainly, a much more complex singularity structure than of a single pole can be expected [40,4,41,42], but this singlepole Ansatz serves our needs here for an application to a concrete case. It is also rich enough to highlight interesting features of the propagator in Minkowski space.…”

Section: Model Calculationmentioning

confidence: 99%

Quark Propagator in Minkowski Space

Solis

Luiz

et al. 2019

Few-Body Syst

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The analytic structure of the quark propagator in Minkowski space is more complex than in Euclidean space due to the possible existence of poles and branch cuts at timelike momenta. These singularities impose enormous complications on the numerical treatment of the nonperturbative Dyson-Schwinger equation for the quark propagator. Here we discuss a computational method that avoids most of these complications. The method makes use of the spectral representation of the propagator and of its inverse. The use of spectral functions allows one to handle in exact manner poles and branch cuts in momentum integrals. We obtain model-independent integral equations for the spectral functions and perform their renormalization by employing a momentum-subtraction scheme. We discuss an algorithm for solving numerically the integral equations and present explicit calculations in a schematic model for the quark-gluon scattering kernel.

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Quark-gluon vertex: A perturbation theory primer and beyond

Cited by 58 publications

References 88 publications

The quark-gluon vertex and the QCD infrared dynamics

The quark-gluon vertex and the QCD infrared dynamics

Non-Abelian Ball-Chiu vertex for arbitrary Euclidean momenta

Quark Propagator in Minkowski Space

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