Abstract
Some known constraints on Renormalization Group flow take the form of inequalities: in even dimensions they refer to the coefficient $a$ of the Weyl anomaly, while in odd dimensions to the sphere free energy $F$. In recent work arXiv:1409.1937 it was suggested that the $a$- and $F$-theorems may be viewed as special cases of a Generalized $F$-Theorem valid in continuous dimension. This conjecture states that, for any RG flow from one conformal fixed point to another, $\tilde F_{\rm UV} > \tilde F_{\rm IR}$, where $\tilde F=\sin (\pi d/2)\log Z_{S^d}$. Here we provide additional evidence in favor of the Generalized $F$-Theorem. We show that it holds in conformal perturbation theory, i.e. for RG flows produced by weakly relevant operators. We also study a specific example of the Wilson-Fisher $O(N)$ model and define this CFT on the sphere $S^{4-\epsilon}$, paying careful attention to the beta functions for the coefficients of curvature terms. This allows us to develop the $\epsilon$ expansion of $\tilde F$ up to order $\epsilon^5$. Pade extrapolation of this series to $d=3$ gives results that are around $2-3\%$ below the free field values for small $N$. We also study RG flows which include an anisotropic perturbation breaking the $O(N)$ symmetry; we again find that the results are consistent with $\tilde F_{\rm UV} > \tilde F_{\rm IR}$.
Highlights
In odd dimensions the situation is quite different because there are no Weyl anomalies
Some known constraints on Renormalization Group flow take the form of inequalities: in even dimensions they refer to the coefficient a of the Weyl anomaly, while in odd dimensions to the sphere free energy F
In recent work [1] it was suggested that the aand F -theorems may be viewed as special cases of a Generalized F -Theorem valid in continuous dimension
Summary
Since the theory is renormalizable, the divergences in the free energy F = − log Z on a general manifold can be cancelled by expressing the bare couplings λ0, a0, b0, c0, η0 in terms of renormalized ones λ, a, b, c, η. After expressing the bare couplings in terms of renormalized ones, the free energy is finite in the limit → 0 for any values of the renormalized parameters λ, a, b, c, η. Combining all results in (3.3), and expressing λ0, b0, c0 in terms of renormalized couplings using (2.3) and (2.5)–(2.7)–(2.8), we find that all poles cancel provided we set the unknown b51 coefficient in the Euler term to This allows to find the Euler beta function βb to order λ5, given in eq (1.7), and determine the fixed point value b∗ to order 4 by (2.22). As a consistency check of this result, we note that it satisfies the Callan-Symanzik equation (2.15) to order λ4 (without the βη term that we have not included here)
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