Abstract
A distinctive feature observed in lattice simulations of confining nonabelian gauge theories, such as Quantum Chromodynamics, is the presence of a dynamical mass for the gauge field in the low energy regime of the theory. In the Gribov-Zwanziger framework in the Landau gauge, such mass is a consequence of the generation of the dimension two condensates $\langle A_\mu^aA_\mu^a\rangle$ and $\langle \bar\varphi_\mu^{ab}\varphi_\mu^{ab}-\bar\omega_\mu^{ab}\omega_\mu^{ab}\rangle$, where $A$ is the gluon field and the fields $\bar\varphi$, $\varphi$, $\bar\omega$, and $\omega$ are Zwanziger's auxiliary fields. In this work, we show that, in the recently developed BRST-invariant version of the Refined Gribov-Zwanziger theory, these condensates can be introduced in a BRST-invariant way for a family of $R_\xi$ gauges. Their values are explicitly computed to first order and turn out to be independent of the gauge parameters contained in the gauge-fixing condition, as expected from the BRST invariance of the formulation. This fact supports the possibility of a gauge-parameter independent nonzero infrared gluon mass, whose value is the same as the one in the Landau gauge.
Highlights
For more than fifty years, the standard way to perform the quantization of a gauge field theory in the continuum has been the Faddeev-Popov procedure [1]
One expects that the actual physical observables do not depend on the choice of the gauge condition, so that every gauge choice should lead to the same physical results
In order to take into account the existence of the gauge copies, a partial solution was proposed by Gribov himself in the Landau gauge, amounting to constrain the functional integration over the gauge fields to a subset of all field configurations so that the Faddeev-Popov operator M, Eq (1), has only positive eigenvalues
Summary
For more than fifty years, the standard way to perform the quantization of a gauge field theory in the continuum has been the Faddeev-Popov procedure [1]. The Faddeev-Popov operator 1⁄2MðAÞab in the Landau gauge, ∂μAaμ 1⁄4 0, 1⁄2MðAÞab 1⁄4 −∂μDaμb 1⁄4 −δab∂2 þ gfabcAcμ∂μ; ð1Þ whose determinant appears in the path integral formulation, acquires zero modes, i.e., eigenfunctions with vanishing eigenvalues, rendering the quantization procedure ill defined. In order to take into account the existence of the gauge copies, a partial solution was proposed by Gribov himself in the Landau gauge, amounting to constrain the functional integration over the gauge fields to a subset of all field configurations so that the Faddeev-Popov operator M, Eq (1), has only positive eigenvalues. This subset is called the Gribov region, and its boundary is called the Gribov horizon.
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