Abstract
We study the Gribov problem in four-dimensional topological Yang-Mills theories following the Baulieu-Singer approach in the (anti-)self-dual Landau gauges. This is a gauge-fixed approach that allows to recover the topological spectrum, as first constructed by Witten, by means of an equivariant (or constrained) BRST cohomology. As standard gauge-fixed Yang-Mills theories suffer from the gauge copy (Gribov) ambiguity, one might wonder if and how this has repercussions for this analysis. The resolution of the small (infinitesimal) gauge copies, in general, affects the dynamics of the underlying theory. In particular, treating the Gribov problem for the standard Landau gauge condition in non-topological Yang-Mills theories strongly affects the dynamics of the theory in the infrared. In the current paper, although the theory is investigated with the same gauge condition, the effects of the copies turn out to be completely different. In other words: in both cases, the copies are there, but the effects are very different. As suggested by the tree-level exactness of the topological model in this gauge choice, the Gribov copies are shown to be inoffensive at the quantum level. To be more precise, following Gribov, we discuss the path integral restriction to the Gribov horizon. The associated gap equation, which fixes the so-called Gribov parameter, is however shown to only possess a trivial solution, making the restriction obsolete. We relate this to the absence of radiative corrections in both gauge and ghost sectors. We give further evidence by employing the renormalization group which shows that, for this kind of topological model, the gap equation indeed forbids the introduction of a massive Gribov parameter.
Highlights
We study the Gribov problem in four-dimensional topological Yang-Mills theories following the BaulieuSinger approach in theself-dual Landau gauges
Treating the Gribov problem for the standard Landau gauge condition in non-topological Yang-Mills theories strongly affects the dynamics of the theory in the infrared
The observables of the theory are defined as the elements of a BRST cohomology that do not depend on the ghost field c, see [14, 16], thereby defining an equivariant cohomology
Summary
The manifold we construct the theory on is a four-dimensional spacetime which is assumed to be Euclidean and flat. The (anti-)self-dual condition for the field strength is convenient to identify the well-known observables of topological theories in four dimensions (see [14]) known as Donaldson polynomials [1], that are described in terms of the instantons — in which we are interested in here. This condition on Fμν (1.9), which is indirectly a condition on the gauge field as Fμν only depends on Aaμ, corresponds to the gauge fixing of the field strength itself, because Fμaν transforms as a gauge field, cf (1.4). Let us first briefly discuss the Gribov problem
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