Xenia Vinzenz scite author profile

We present the development of a novel integrated device for airborne nanoparticle filtering with bioinspired nanoscale functionality. The underlying idea is to investigate the principle of adherent surfaces, e.g. pollen, as a biological model and transfer this functionality into a technology using functionalized microstructured surfaces. This might offer an efficient filtering method for nanoscale airborne particles without the limitations in gas permeability of conventional filters. We investigated the different pollen species for their structural and biochemical surface properties to achieve bioinspired surface functionality on silicon surfaces. The resulting conical structures have sizes from 4 to 20 μm. Depending on structure sizes, the adhesive properties of the surfaces towards aerosol particles could be directly influenced. The surfaces were tested in a demonstrator setup and the collection efficiency visually determined

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Efficient nanoparticle filtering using bioinspired functional sufaces

Büsch

Ketterer

Vinzenz

et al. 2013

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X-ray structure of chemically engineered Mycobacterium tuberculosis Dodecin

Vinzenz¹,

Große²,

Linne³

et al. 2011

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Xenia Vinzenz

Chemical engineering of Mycobacterium tuberculosis dodecin hybrids

Preparation and characterization of poly(l-histidine)/poly(l-glutamic acid) multilayer on silicon with nanometer-sized surface structures

Evaluation of bioinspired functional surfaces for nanoparticle filtering

Efficient nanoparticle filtering using bioinspired functional sufaces

X-ray structure of chemically engineered Mycobacterium tuberculosis Dodecin

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