We try to review the main current ideas and points of view on the running coupling constant in QCD. We begin by recalling briefly the classic analysis based on the Renormalization Group Equations with some emphasis on the exact solutions for a given number of loops, in comparison with the usual approximate expressions. We give particular attention to the problem of eliminating the unphysical Landau singularities, and of defining a coupling that remains significant at infrared scales. We consider various proposals for couplings directly related to the quark-antiquark potential or to other physical quantities (effective charges) and discuss optimization in the choice of the scale parameter and of the renormalization scheme. Our main focus is, however, on dispersive methods, their application and their relation with non-perturbative effects. We try also to summarize the main results obtained by Lattice simulations, in particular various MOM schemes. We conclude by briefly recalling the traditional comparisons with experimental data.
On the running coupling constant in QCD / G.M. Prosperi, M. Raciti, C. Simolo. - In: PROGRESS IN PARTICLE AND NUCLEAR PHYSICS. - ISSN 0146-6410. - 58:2(2007), pp. 387-438.
On the running coupling constant in QCD
G.M. ProsperiPrimo
;M. RacitiSecondo
;C. SimoloUltimo
2007
Abstract
We try to review the main current ideas and points of view on the running coupling constant in QCD. We begin by recalling briefly the classic analysis based on the Renormalization Group Equations with some emphasis on the exact solutions for a given number of loops, in comparison with the usual approximate expressions. We give particular attention to the problem of eliminating the unphysical Landau singularities, and of defining a coupling that remains significant at infrared scales. We consider various proposals for couplings directly related to the quark-antiquark potential or to other physical quantities (effective charges) and discuss optimization in the choice of the scale parameter and of the renormalization scheme. Our main focus is, however, on dispersive methods, their application and their relation with non-perturbative effects. We try also to summarize the main results obtained by Lattice simulations, in particular various MOM schemes. We conclude by briefly recalling the traditional comparisons with experimental data.
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