Correlation length-exponent relation for the two-dimensional random Ising model

• Main Authors: Lajko, Peter, Igloi, Ferenc
• Format: Journal Article
• Language: English
• Published: 26.08.1999
• Subjects: Physics - Disordered Systems and Neural Networks
• DOI: 10.48550/arxiv.cond-mat/9908376

We consider the two-dimensional (2d) random Ising model on a diagonal strip of the square lattice, where the bonds take two values, $J_1>J_2$, with equal probability. Using an iterative method, based on a successive application of the star-triangle transformation, we have determined at the bulk critical temperature the correlation length along the strip, $\xi_L$, for different widths of the strip, $L \le 21$. The ratio of the two lengths, $\xi_L/L=A$, is found to approach the universal value, $A=2/\pi$ for large $L$, independent of the dilution parameter, $J_1/J_2$. With our method we have demonstrated with high numerical precision, that the surface correlation function of the 2d dilute Ising model is self-averaging, in the critical point conformally coovariant and the corresponding decay exponent is $\eta_{\parallel}=1$.