Stiffness Exponents for Lattice Spin Glasses in Dimensions d=3,...,6

Abstract

The stiffness exponents in the glass phase for lattice spin glasses in dimensions d=3,...,6 are determined. To this end, we consider bond-diluted lattices near the T=0 glass transition point p*. This transition for discrete bond distributions occurs just above the bond percolation point pc in each dimension. Numerics suggests that both points, pc and p*, seem to share the same 1/d-expansion, at least for several leading orders, each starting with 1/(2d). Hence, these lattice graphs have average connectivities of α=2dp1 near p* and exact graph-reduction methods become very effective in eliminating recursively all spins of connectivity ≤3, allowing the treatment of lattices of lengths up to L=30 and with up to 105-106 spins. Using finite-size scaling, data for the defect energy width σ( E) over a range of p>p* in each dimension can be combined to reach scaling regimes of about one decade in the scaling variable L(p-p*)^*. Accordingly, unprecedented accuracy is obtained for the stiffness exponents compared to undiluted lattices (p=1), where scaling is far more limited. Surprisingly, scaling corrections typically are more benign for diluted lattices. We find in d=3,...,6 for the stiffness exponents y3=0.24(1), y4=0.61(2), y5=0.88(5), and y6=1.1(1). The result for the upper critical dimension, du=6, suggest a mean-field value of y∞=1.

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