Scaling of Long-Range Loop-Erased Random Walks

Abstract

We study the scaling properties of long-range loop-erased random walks (LR-LERW), where the underlying random walker performs L\'evy-flight-like jumps with a power-law step-length distribution P(r) |r|-(d+σ). Using extensive Monte Carlo simulations, we measure the scaling relation N RdN between the loop-erased step number N and the spatial extent R, and determine the geometric exponent dN for various values of σ in spatial dimensions d = 1, 2, and 3, as well as at the marginal point σ = 2 in d=4 and 5. We observe a continuous crossover from long-range (LR) to short-range (SR) behavior as σ increases. Below the upper critical dimension d<dc=4, for σ < d/2, loop erasure is asymptotically irrelevant and dN=σ, consistent with L\'evy-flight scaling. For d/2 < σ < 2, loop erasure becomes relevant and dN varies continuously toward the SR-LERW value. At the marginal points with σ=d/2 or σ=2, clear logarithmic corrections are observed. At and above the upper critical dimension, d ≥ 4, the scaling at σ=2 is found to be N R2/ R, consistent with that of the corresponding L\'evy flight. Our results provide a systematic numerical determination of dN(σ) for the LR-LERW across dimensions, and are consistent with σ* = 2 as the boundary between LR and SR critical behaviors recently established in a broad variety of statistical models.

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