A Unified Computational Framework for Two Dimensional Diffusion Limited Aggregation via Finite-Size Scaling, Multifractality, and Morphological Analysis

Abstract

Diffusion-Limited Aggregation (DLA), the canonical model for non-equilibrium fractal growth, emerges from the simple rule of irreversible attachment by random walkers. Despite four decades of study, a unified computational framework reconciling its stochastic algorithm, universal fractal dimension, multifractal growth measure, and finite-size effects remains essential for applications from materials science to geomorphology. Through large-scale simulations (clusters up to N = 106 particles) in two dimensions, we perform a tripartite analysis: (1) We establish a definitive finite-size scaling collapse, extracting the universal fractal dimension D = 1.712 0.015 and identifying the crossover to boundary-dominated growth at a scaled mass x0 ≈ 0.10 0.02. (2) We quantify the full multifractal spectrum of the harmonic measure (α ≈ 1.13), directly linking the stochastic algorithm to the deterministic Laplacian growth equation ∇2 p = 0 and explaining the screening effect via an exponential decay η e-r/ with screening length = 22.7 0.8 lattice units. (3) We provide a complete morphological characterization, revealing power-law branch length distributions (τ ≈ 2.1) and angular branching preferences ( 72). This work computationally validates DLA as a robust universality class and provides a scalable methodology for analyzing diffusion-controlled pattern formation across disciplines.