Abstract
Block-spin transformation of topological defects is applied to the violation of the non-Abelian Bianchi identity (VMABI) on lattice defined as Abelian monopoles. To get rid of lattice artifacts, we introduce various techniques smoothing the vacuum. The effective action can be determined by adopting the inverse Monte-Carlo method. The coupling constants $F(i)$ of the effective action depend on the coupling of the lattice action $\beta$ and the number of the blocking step $n$. But it is found that $F(i)$ satisfy a beautiful scaling, that is, they are a function of the product $b=na(\beta)$ alone for lattice coupling constants $3.0\le\beta\le3.9$ and the steps of blocking $1\le n\le 12$. The effective action showing the scaling behavior can be regarded as an almost perfect action corresponding to the continuum limit, since $a\to 0$ as $n\to\infty$ for fixed $b$. The almost perfect action showing the scaling is found to be independent of the smooth gauges adopted here. Then we compare the results with those obtained by the analytic blocking method of topological defects from the continuum. The infrared monopole action can be transformed into that of the string model. The physical string tension and the lowest glueball mass can be evaluated \textit{analytically} by the strong-coupling expansion of the string model. We get $\sqrt{\sigma}\simeq 1.3\sqrt{\sigma_{phys}}$ for $b\ge 1.0\ \ (\sigma_{phys}^{-1/2})$, whereas the scalar glueball mass is kept to be near $M(0^{++})\sim 3.7\sqrt{\sigma_{phys}}$. Also we can almost reproduce \textit{analytically} the scaling function of the squared monopole density determined numerically for large $b$ region $b>1.2\ (\sigma_{phys}^{-1/2})$.
Highlights
It is shown in the continuum limit that the violation of the non-Abelian Bianchi identities (VNABI) Jμ is equal to Abelian-like monopole currents kμ defined by the violation of the Abelian-like Bianchi identities [1,2]
We evaluate the string tension σlat from the monopole part of the Abelian Wilson loops for each β since the error bars are small rinelathtiiosncaasðeβ.ÞT1⁄4heplaffiσtffitffilffiiafficffitffie=ffiffiffiσsffiffippffiffihffiaffiyfficsffi.inNgoateðβthÞaitsbgi1⁄4ve1n.0bσy−pht1hy=se2
The 10 coupling constants FðiÞði 1⁄4 1–10Þ of quadratic interactions are fixed very beautifully for lattice coupling constants 3.0 ≤ β ≤ 3.9 and the steps of blocking 1 ≤ n ≤ 12. They are all expressed by a function of b 1⁄4 naðβÞ alone, they originally depend on two parameters β and n
Summary
It is shown in the continuum limit that the violation of the non-Abelian Bianchi identities (VNABI) Jμ is equal to Abelian-like monopole currents kμ defined by the violation of the Abelian-like Bianchi identities [1,2]. The color invariant eigenvalue λμ of VNABI satisfies the Abelian conservation rule ∂μλμ 1⁄4 0 and the magnetic charge of the eigenvalue is quantized ala Dirac. An. Abelian-like definition of a monopole following DeGrandToussaint [3] is adopted as a lattice version of VNABI, since the Dirac quantization condition of the magnetic charge is taken into account on lattice. Of the lattice VNABI density is studied by introducing various techniques of smoothing the thermalized vacuum which is contaminated by lattice artifacts originally With these improvements, beautiful and convincing scaling behaviors are seen when we plot the density. In this paper we perform the blockspin renormalization-group study of lattice SUð2Þ gauge theory and try to get the infrared effective VNABI action by introducing a blockspin transformation of lattice VNABI (Abelian monopoles). It is interesting to see the numerically determined scaling behavior of RðbÞ can almost be reproduced analytically by the simple monopole action for b > 1.2ðσ−ph1y=s2Þ, there remains around 30% discrepancy due mainly to the choice of simplest 10 quadratic monopole interactions alone
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