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Random Defect Lines in Conformal Minimal Models

arXiv:cond-mat/9910181 · doi:10.1016/S0550-3213(00)00639-8

Abstract

We analyze the effect of adding quenched disorder along a defect line in the 2D conformal minimal models using replicas. The disorder is realized by a random applied magnetic field in the Ising model, by fluctuations in the ferromagnetic bond coupling in the Tricritical Ising model and Tricritical Three-state Potts model (the $ϕ_{12}$ operator), etc.. We find that for the Ising model, the defect renormalizes to two decoupled half-planes without disorder, but that for all other models, the defect renormalizes to a disorder-dominated fixed point. Its critical properties are studied with an expansion in $\eps \propto 1/m$ for the mth Virasoro minimal model. The decay exponents $X_N=\frac{N}{2}(1-\frac{9(3N-4)}{4(m+1)^2}+ \mathcal{O}(\frac{3}{m+1})^3)$ of the Nth moment of the two-point function of $ϕ_{12}$ along the defect are obtained to 2-loop order, exhibiting multifractal behavior.This leads to a typical decay exponent $X_{\rm typ}={1/2} (1+\frac{9}{(m+1)^2}+\mathcal{O}(\frac{3}{m+1})^3)$. One-point functions are seen to have a non-self-averaging amplitude. The boundary entropy is larger than that of the pure system by order 1/m^3. As a byproduct of our calculations, we also obtain to 2-loop order the exponent $\tilde{X}_N=N(1-\frac{2}{9π^2}(3N-4)(q-2)^2+\mathcal{O}(q-2)^3)$ of the Nth moment of the energy operator in the q-state Potts model with bulk bond disorder.

33 pages, 6 figures, LaTex