A competitive growth model (CGM) describes the aggregation of a single type of particle under two different growth rules with occurrence probabilities p and 1−p. We explain the origin of the scaling behavior of the resulting surface roughness at small p for two CGM’s which describe random deposition (RD) competing with ballistic deposition and RD competing with the Edward-Wilkinson (EW) growth rule. Exact scaling exponents are derived. The scaling behavior of the coefficients in the corresponding continuum equations are also deduced. Furthermore, we suggest that, in some CGM’s, the p dependence on the coefficients of the continuum equation that represents their universality class can be nontrivial. In some cases, the process cannot be repre...
We study scaling properties of the surface morphology at epitaxial growth in a generalized...
We present simulation results of deposition growth of surfaces in two, three, and four dimensions fo...
4 pages, 3 figures.-- PACS nrs.: 05.40.+j, 05.70.Ln, 68.35.Fx, 81.15.Pq.-- ArXiv pre-print available...
2005-2006 > Academic research: refereed > Publication in refereed journalVersion of RecordPublishe
In this work we have reported the evolution of rough surface by different competitive growth model i...
In this work we have reported the evolution of rough surface by different competitive growth model i...
We study the ballistic deposition and the grain deposition models on two-dimensional substrates. Usi...
Non-equilibrium surface growth for competitive growth models in (1+1) dimensions, particularly mixin...
The pattern structure and the scaling behavior of the surface width for two deposition models of two...
The question of the validity of the scaling ansatz in discrete deposition models and their connectio...
In this work, we introduce a restricted ballistic deposition model with symmetric growth rules that ...
Abstract. We calculate the width of the growing interface of ballistic aggregation in the limit in w...
We performed extensive Monte Carlo simulations of the ballistic deposition model in (1 + 1)-dimensio...
In this dissertation, I present a number of theoretical and numerical studies of the dynamic scaling...
We study the dynamics of growth at the interface level for two different kinetic models. Both of the...
We study scaling properties of the surface morphology at epitaxial growth in a generalized...
We present simulation results of deposition growth of surfaces in two, three, and four dimensions fo...
4 pages, 3 figures.-- PACS nrs.: 05.40.+j, 05.70.Ln, 68.35.Fx, 81.15.Pq.-- ArXiv pre-print available...
2005-2006 > Academic research: refereed > Publication in refereed journalVersion of RecordPublishe
In this work we have reported the evolution of rough surface by different competitive growth model i...
In this work we have reported the evolution of rough surface by different competitive growth model i...
We study the ballistic deposition and the grain deposition models on two-dimensional substrates. Usi...
Non-equilibrium surface growth for competitive growth models in (1+1) dimensions, particularly mixin...
The pattern structure and the scaling behavior of the surface width for two deposition models of two...
The question of the validity of the scaling ansatz in discrete deposition models and their connectio...
In this work, we introduce a restricted ballistic deposition model with symmetric growth rules that ...
Abstract. We calculate the width of the growing interface of ballistic aggregation in the limit in w...
We performed extensive Monte Carlo simulations of the ballistic deposition model in (1 + 1)-dimensio...
In this dissertation, I present a number of theoretical and numerical studies of the dynamic scaling...
We study the dynamics of growth at the interface level for two different kinetic models. Both of the...
We study scaling properties of the surface morphology at epitaxial growth in a generalized...
We present simulation results of deposition growth of surfaces in two, three, and four dimensions fo...
4 pages, 3 figures.-- PACS nrs.: 05.40.+j, 05.70.Ln, 68.35.Fx, 81.15.Pq.-- ArXiv pre-print available...