Finite-size scaling in quasi-3D stick percolation

TL;DR

This paper extends finite-size scaling theory to quasi-3D stick systems, showing that their percolation behavior is universal and similar to 2D systems, with a higher percolation threshold determined via Monte Carlo simulations.

Contribution

It introduces a universal finite-size scaling framework for Q3D stick percolation, demonstrating scale invariance and universality with 2D percolation models.

Findings

Percolation threshold for Q3D is approximately 21.5% higher than 2D.

Threshold is independent of wire diameter-to-length ratio.

Q3D percolation follows the same universal scaling function as 2D percolation.

Abstract

This work extends the universal finite-size scaling framework for continuum percolation from two-dimensional (2D) to quasi-three-dimensional (Q3D) stick systems, in which sequentially deposited wires of finite diameter stack vertically on a flat substrate. Using Monte Carlo simulation, the percolation threshold is determined for isotropic Q3D stick systems as $N_c l^2 = 6.850923 \pm 0.00014$, approximately $21.5\%$ above the established 2D value of $5.6373$. The threshold is shown to be independent of the wire diameter-to-length ratio $d/l$, reflecting the scale invariance of the contact topology under sequential deposition. Simulation results indicate that, as with 2D networks, by introducing a nonuniversal metric factor, the spanning probability of Q3D stick percolation on square systems with free boundary conditions falls on the same universal scaling function as that for 2D continuum and lattice percolation. This provides substantiating evidence that Q3D stick percolation falls on the same universal scaling function as that for 2D stick percolation and lattice percolation.