Morphology and Kinetics of Random Sequential Adsorption of Superballs: From Hexapods to Cubes

Abstract

Superballs represent a class of particles whose shapes are defined by |x|2p+|y|2p+|z|2p R2p, with p∈(0,∞) being the "deformation parameter". 0<p<0.5 represents a family of hexapodlike (concave octahedrallike) particles, while for 0.5≤ p<1 and p>1 one has, respectively, families of convex octahedrallike and cubelike particles, with p=1,\;0.5 and ∞ representing spheres, octahedra, and cubes. Colloidal zeolite suspensions, catalysis, and adsorption, as well as biomedical magnetic nanoparticles are but a few of the applications of packing of superballs. We introduce a universal method for simulating random sequential adsorption of superballs, which we refer to as "low-entropy" algorithm, in contrast with the conventional algorithm that represents a "high-entropy" method. The two algorithms yield, respectively, precise estimates of the jamming fraction φ∞(p) and (p), the exponent that characterizes the kinetics of adsorption at long times t, φ(∞)-φ(t) t-(p). Precise estimates of φ∞(p) and (p) are obtained and shown to be in agreement, in some special limits, with the existing analytical and numerical results.