posted on 2022-10-20, 12:35authored byMaria Morga, Małgorzata Nattich-Rak, Zbigniew Adamczyk, Damian Mickiewicz, Mariusz Gadzinowski, Teresa Basinska
Anisotropic particle
deposition was investigated using the streaming
potential method complemented with the atomic force microscopy (AFM)
determination of the absolute particle coverage. The polymer particles
were synthesized using the stretching procedure with consecutive oxidation
of surface hydroxyl groups and coupling of polyethyleneimine. The
bulk particle physicochemical properties were characterized by scanning
electron microscopy (SEM), dynamic light scattering, and laser Doppler
velocimetry. The particles were positively charged in the pH range
of 3–10, exhibiting a prolate spheroid shape with an axis ratio
of five. Thorough AFM and in situ optical microscopy measurements
yielded the adsorption kinetics of particles under the diffusion-controlled
regime. The experimental data were adequately interpreted in terms
of the random sequential adsorption model with the surface blocking
function derived from the scaled particle theory. The root-mean-square
(rms) parameter of the layers for a broad range of particle coverage
was also determined and interpreted using the topographical model
developed in this work. The experiments were complemented by the measurements
of the streaming potential of particle layers under various ionic
strengths and pHs. The ζ (zeta)-potential data acquired in this
way enabled to determine the universal hydrodynamic function describing
the dependence of the streaming potential on the particle coverage.
The function was used to express the ζ-potential of surfaces
covered by particles in terms of substrate rms. It was argued that
the acquired results, in addition to being significanct to basic science,
can be exploited as useful reference systems for quantitative interpretation
of bioparticle deposition on abiotic surfaces.