A molecular dynamics study of surface-directed spinodal decomposition on a chemically patterned amorphous substrate
Abstract
We employ a molecular dynamics (MD) study to explore pattern selection in binary fluid mixtures (AB) undergoing surface-directed spinodal decomposition on a chemically patterned amorphous substrate. We chose a checkerboard pattern with chemically distinct square patches of a side M, with neighboring patches preferring different particle types. We report the efficient transposition of the substrate's pattern as a registry to the fluid cross sections in its vicinity when the pattern's periodicity λ/σ 2M (σ being the fluid particle size) is larger than the mixture's spinodal length scale λc/σ 2π/B (B being the bulk correlation length). Our correlation analysis between the surface field and the surface-registries in the substrate's normal direction shows that the associated decay length, L(t), increases with decreasing pattern periodicity (λ). L(t) also exhibits diffusive growth with time t1/3, similar to wetting-layer growth for chemically homogeneous walls. Our MD results also show the emergence of composition waves parallel to the substrate, whose wavelength exhibits dynamical scaling with a power-law growth in time L||(z,t) tα. L||(z,t) shows dynamical crossovers from a transient surface-registry regime to universal phase-separation regimes for cross-sections with registries. We also give an account of the scaling of registry's formation and melting times with patch sizes.
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