We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Ionic Diffusiophoresis of Active Colloids via Galvanic Exchange Reactions
Summary
This study investigates ionic diffusiophoresis of active colloids that undergo galvanic exchange reactions, exploring how chemical gradients drive directed particle motion in electrolyte solutions; the work is relevant to nano-scale transport physics rather than microplastic ecology.
In order to move toward realistic applications by extending active matter propulsion reactions beyond the classical catalytic hydrogen peroxide decomposition, we investigate the self-propulsion mechanism of Janus particles. To address the influences of ionic species, we investigate Janus particles driven by a galvanic exchange reaction that consumes and produces ions on one hemisphere. Our galvanophoretic experiments in the regime of thin Debye layers confirm that even the simplest models in active matter are still full of important surprises. We find a logarithmic speed dependence on the fuel concentration, which cannot be explained using the classic ionic self-diffusiophoretic framework. Instead, an approach based on the Poisson-Nernst-Planck equations yields a better agreement with the experiments. We attribute the discrepancy between the two models to the breakdown of two key hypotheses of the ionic self-diffusiophoretic approach.
Sign in to start a discussion.
More Papers Like This
Diffusiophoresis: a novel transport mechanism - fundamentals, applications, and future opportunities
This paper is not primarily about microplastics. It reviews diffusiophoresis, a physical transport mechanism where particles move in response to chemical concentration gradients, covering both fundamental science and applications in water filtration, drug delivery, and biological systems. While the removal of microplastics is briefly mentioned as one potential application of active diffusiophoresis, the paper is a broad physics review rather than a study of microplastic pollution.
Diffusiophoretic transport of colloids in porous media
This study is not primarily about microplastics; it investigates how chemical gradients (diffusiophoresis) change how colloidal particles move through porous media in general. Microplastic remediation is mentioned as one potential application area, but the work is fundamentally a fluid physics study.
Estimating the velocity of chemically-driven Janus colloids considering the anisotropic concentration field
This theoretical study calculated the self-propulsion velocity of Janus colloids — particles with two distinct chemical surfaces — driven by concentration gradients from their own chemical reactions. The anisotropic concentration field around the particle plays a key role in determining speed. Understanding active particle motion has implications for designing drug delivery systems and microplastic remediation using active colloids.
Review: Interactions of Active Colloids with Passive Tracers
This review examines how self-propelled particles (active colloids) interact with passive objects in their environment, drawing parallels between artificial systems and biological ones like bacteria. The findings have relevance for understanding how microplastics may be transported or aggregated by microorganisms in water.
Modelling of Diffusiophoretic Motion for Microplastic Filtration in Microchannel Flows.
Researchers developed microchannel designs that harness diffusiophoresis -- particle motion driven by electrolyte solute gradients in a cross-flow orientation -- to filter micrometer-sized particles such as microplastics from water. The modeling study demonstrates the potential of this mechanism to enable low-cost, decentralized water filtration without energy-intensive pressure-driven systems.