English

Multiple Invaded Consolidating Materials

Disordered Systems and Neural Networks 2009-11-10 v1 Statistical Mechanics

Abstract

We study a multiple invasion model to simulate corrosion or intrusion processes. Estimated values for the fractal dimension of the invaded region reveal that the critical exponents vary as function of the generation number GG, i.e., with the number of times the invasion process takes place. The averaged mass MM of the invaded region decreases with a power-law as a function of GG, MGβM\sim G^{\beta}, where the exponent β0.6\beta\approx 0.6. We also find that the fractal dimension of the invaded cluster changes from d1=1.887±0.002d_{1}=1.887\pm0.002 to ds=1.217±0.005d_{s}=1.217\pm0.005. This result confirms that the multiple invasion process follows a continuous transition from one universality class (NTIP) to another (optimal path). In addition, we report extensive numerical simulations that indicate that the mass distribution of avalanches P(S,L)P(S,L) has a power-law behavior and we find that the exponent τ\tau governing the power-law P(S,L)SτP(S,L)\sim S^{-\tau} changes continuously as a function of the parameter GG. We propose a scaling law for the mass distribution of avalanches for different number of generations GG.

Cite

@article{arxiv.cond-mat/0409203,
  title  = {Multiple Invaded Consolidating Materials},
  author = {A. D. Araujo and J. S. Andrade and H. J. Herrmann},
  journal= {arXiv preprint arXiv:cond-mat/0409203},
  year   = {2009}
}

Comments

8 pages and 16 figures