Papers
Topics
Authors
Recent
Search
2000 character limit reached

Generalization of Faddeev--Popov Rules in Yang--Mills Theories: N=3,4 BRST Symmetries

Published 30 Dec 2016 in hep-th, math-ph, math.MP, and math.RT | (1701.00009v5)

Abstract: The Faddeev-Popov rules for quantization of theory with gauge group are generalized for case of nvariance of quantum actions, $S_N$, on N-parametric Abelian SUSY transformations with odd parameters $\lambda_p$, p=1,..,N and anticommuting generators $s_p$, for N=3,4 implying substitution of ghost fields N-plet, $Cp$ multipled on $\lambda_p$, instead of the parameter, $\xi$, of gauge transformations. Total configuration spaces for quantum theory of the same classical model coincide for N=3 ,4 cases. For N=3 transformations the superspace of irrep includes in addition 3 ghost $Cp$, 3 even $B{pq}$ and odd $\hat{B}$ fields for p,q=1-3. It is shown for quantum action $S_{3}$ the gauge-fixing by adding to classical action of N=3-exact term requires 1 antighost $\bar{C}$, 3 even $B{p}$ 3 odd $\hat{B}{}p$ and Nakanishi--Lautrup fields. Action of N=3 transformations on the latter fields is found. The transformations appear by N=3 BRST ones for the vacuum functional, $Z_3(0) $. It is shown, the configuration space appears by irrep superspace for fields $\Phi_4$ for N=4- transformations containing in addition to $A\mu$: (4+6+4+1) ghost-antighost $Cr$, even $B{rs}$, odd $\hat{B}{}r $ fields and B. Action $S_4$ is constructed by adding to classical action of N=4-exact with gauge boson $F_4$ as compared to gauge fermion $\Psi_3$ for N=3 case. Procedure is valid for any admissible gauge. The equivalence with $N=1$ BRST-invariant quantization method is explicitly found. Finite N=3,4 BRST transformations are derived from algebraic transformations. Respective Jacobians for field-dependent parameters are calculated. They imply the presence of corresponding modified Ward identity to be reduced to new (usual) Ward identities for constant parameters and describe the problem of gauge-dependence. Introduction into diagrammatic Feynman techniques for N=3,4 cases is suggested.

Authors (1)

Summary

No one has generated a summary of this paper yet.

Paper to Video (Beta)

No one has generated a video about this paper yet.

Whiteboard

No one has generated a whiteboard explanation for this paper yet.

Open Problems

We haven't generated a list of open problems mentioned in this paper yet.

Continue Learning

We haven't generated follow-up questions for this paper yet.

Collections

Sign up for free to add this paper to one or more collections.