Abstract
State-of-the-art dielectrophoretic (DEP) separation techniques provide unique properties to separate particles from a liquid or particles with different properties such as material or morphology from each other. Such separators do not operate at throughput that is sufficient for a vast fraction of separation tasks. This limitation exists because high electric field gradients are required to drive the separation which are generated by electrode microstructures that limit the maximum channel size. Here, we investigate DEP filtration, a technique that uses open porous microstructures instead of microfluidic devices to easily increase the filter cross section and, therefore, also the processable throughput by several orders of magnitude. Previously, we used simple microfluidic porous structures to derive design rules predicting the influence of key parameters on DEP filtration in real complex porous filters. Here, we study in depth DEP filtration in microporous ceramics and underpin the previously postulated dependencies by a broad parameter study (Lorenz et al., 2019). We will further verify our previous claim that the main separation mechanism is indeed positive DEP trapping by showing that we can switch from positive to negative DEP trapping when we increase the electric conductivity of the suspension. Two clearly separated trapping mechanisms (positive and negative DEP trapping) at different conductivities can be observed, and the transition between them matches theoretical predictions. This lays the foundation for selective particle trapping, and the results are a major step towards DEP filtration at high throughput to solve existing separation problems such as scrap recovery or cell separation in liquid biopsy.Graphical abstract
Highlights
Published in the topical collection Bioanalytics and Higher Order Electrokinetics with guest editors Mark A
The good match between DEP simulation and filtration in a real random and inhomogeneous macroscopic structure was by no means obvious, since fluid dynamics and electrokinetics are highly complex in such systems
It remained an open question, if the main trapping is DEP driven or due to other DEP-related, nonlinear electrokinetic effects that were reported in macroscopic structures [33]
Summary
Published in the topical collection Bioanalytics and Higher Order Electrokinetics with guest editors Mark A. Separation of micron and sub-micron particles from liquid media or according to their properties is essential for a wide variety of fields. It is a key for (bio-)analytics and medical diagnostics [1], for example for cell separation in liquid biopsy, as well as product purification [2]; for recovery and mining of valuable materials [3,4,5]; or to increase the sustainability and cost efficiency of industrial processes. At small particle scales (of the dimension of cells or fine dust), density separation fails as the weight differences become negligible and size exclusion mechanisms require high pressure differences to achieve significant throughputs.
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