Multiscale Modelling of Morphological Evolution of Rough Surface during Superficial, Volume and Evaporation-Condensation Diffusions

M. Bigerelle; Jérôme Favergeon; T. Mathia; Alain Iost

doi:10.4028/www.scientific.net/DDF.323-325.101

Paper Titles

²⁶Al Tracer Diffusion in Nominally Undoped Single Crystalline α-Al₂O₃
p.75

Numerical Aspects of Electrodiffusion Problem Based on Nernst-Planck and Poisson Equations
p.81

Study of the Reactive Dynamics of Nanometric Metallic Multilayers Using Molecular Dynamics : The Al-Ni System
p.89

Atomistic Simulation of Clustering and Annihilation of Point Defects in Molybdenum
p.95

Multiscale Modelling of Morphological Evolution of Rough Surface during Superficial, Volume and Evaporation-Condensation Diffusions
p.101

Simulation of Metal/Oxide Interface Mobility: Effects of Mechanical Stresses on Geometrical Singularities
p.109

High Temperature Diffusion Processes at the Metal/Slag Interface
p.115

Modeling of Fractional Diffusion on a Catalytic Particle under Different Flow Conditions
p.121

Modeling of Multi-Phase Solid State Reactions-Case of IMC Growth
p.127

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Multiscale Modelling of Morphological Evolution of Rough Surface during Superficial, Volume and Evaporation-Condensation Diffusions

Abstract:

Fractal functions are used to model a metallic interface. An analytical model described by three partial differential equations is built to model time evolution of the surface during heating including three different mechanisms of diffusion: superficial diffusion (SD), volume diffusion (VD) and diffusion by evaporation-condensation (DEC). Initial topographies are modeled by Stochastic Weierstraβ functions because of their ability to reproduce experimental roughness profiles. Applied to an aluminum alloy at 550°C, a high number of roughness parameters and their variance are calculated. A classification method shows that the best geometrical approach that discriminates heat effect is the fractal dimension. The most popular parameter, R_a, badly discriminates processes (classification number = 58). The four order spectral moments of the roughness profile are correlated with the evolution of profile. It is shown theoretically that the superficial diffusion depends directly to the fourth spectral moment of the roughness profile.