Anna Pohl scite author profile

The geometric and electronic structure of condensed phase organic conducting polymer PEDOT:PSS blends has been investigated by periodic density functional theory (DFT) calculations with a generalized-gradient approximation (GGA) functional, and a plane wave basis set. The influence of the degree of doping of the PEDOT polymer on structural and optical parameters such as the reflectivity, absorbance, conductivity, dielectric function, refractive index and the energy-loss function is studied. A flip from the benzoid to the quinoid structure is observed in the calculations when the neutral PEDOT is doped by negatively charged PSS. Also the optical properties are affected by the doping. In particular, the reflectivity was found to be very sensitive to the degree of doping, where higher doping implies higher reflectivity. The reflectivity is highly anisotropic, with the dominant contribution stemming from the direction parallel to the PEDOT polymer chain.

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Radular stylus of Cryptochiton stelleri: A multifunctional lightweight and flexible fiber-reinforced composite

Pohl

Herrera

Restrepo

et al. 2020

Journal of the Mechanical Behavior of Biomedical Materials

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Decoding Biomineralization: Interaction of a Mad10-Derived Peptide with Magnetite Thin Films

et al. 2019

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Protein−surface interactions play a pivotal role in processes as diverse as biomineralization, biofouling, and the cellular response to medical implants. In biomineralization processes, biomacromolecules control mineral deposition and architecture via complex and often unknown mechanisms. For studying these mechanisms, the formation of magnetite nanoparticles in magnetotactic bacteria has become an excellent model system. Most interestingly, nanoparticle morphologies have been discovered that defy crystallographic rules (e.g., in the species Desulfamplus magnetovallimortis strain BW-1). In certain conditions, this strain mineralizes bullet-shaped magnetite nanoparticles, which exhibit defined (111) crystal faces and are elongated along the [100] direction. We hypothesize that surface-specific protein interactions break the nanoparticle symmetry, inhibiting the growth of certain crystal faces and thereby favoring the growth of others. Screening the genome of BW-1, we identified Mad10 (Magnetosome-associated deep-branching) as a potential magnetite-binding protein.Using atomic force microscope (AFM)-based single-molecule force spectroscopy, we show that a Mad10-derived peptide, which represents the most conserved region of Mad10, binds strongly to (100)-and ( 111)-oriented single-crystalline magnetite thin films. The peptide− magnetite interaction is thus material-but not crystal-face-specific. It is characterized by broad rupture force distributions that do not depend on the retraction speed of the AFM cantilever. To account for these experimental findings, we introduce a three-state model that incorporates fast rebinding. The model suggests that the peptide−surface interaction is strong in the absence of load, which is a direct result of this fast rebinding process. Overall, our study sheds light on the kinetic nature of peptide−surface interactions and introduces a new magnetitebinding peptide with potential use as a functional coating for magnetite nanoparticles in biotechnological and biomedical applications.

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Spin and orbital magnetism in 3dsystems

et al. 1990

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We present self-consistent linear mu5n-tin orbitals calculations for the cubic systems bcc Fe (a-Fe), YFe2, FeA1, and Fe3A1, and the hexagonal compounds ThFe5 and Fe2P. The spin-polarized calculations include the spin-orbit coupling and both the spin and orbital moments are reported. A simple model calculation is presented for a-Fe and from this it is concluded that the low orbital moments in the presently investigated 3d systems can be understood from the symmetry-adapted wave functions of the crystal.

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Real-time monitoring of calcium carbonate and cationic peptide deposition on carboxylate-SAM using a microfluidic SAW biosensor

Pohl¹,

Weiss²

2014

Beilstein J. Nanotechnol.

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SummaryA microfluidic biosensor with surface acoustic wave technology was used in this study to monitor the interaction of calcium carbonate with standard carboxylate self-assembled monolayer sensor chips. Different fluids, with and without biomolecular components, were investigated. The pH-dependent surface interactions of two bio-inspired cationic peptides, AS8 and ES9, which are similar to an extracellular domain of the chitin synthase involved in mollusc shell formation, were also investigated in a biological buffer system. A range of experimental conditions are described that are suitable to study non-covalent molecular interactions in the presence of ionic substances, such as, mineral precursors below the solubility equilibrium. The peptide ES9, equal to the mollusc chitin synthase epitope, is less sensitive to changes in pH than its counterpart AS8 with a penta-lysine core, which lacks the flanking acidic residues. This study demonstrates the extraordinary potential of microfluidic surface acoustic wave biosensors to significantly expand our experimental capabilities for studying the principles underlying biomineralization in vitro.

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Anna Pohl

The electronic structure and reflectivity of PEDOT:PSS from density functional theory

Radular stylus of Cryptochiton stelleri: A multifunctional lightweight and flexible fiber-reinforced composite

Decoding Biomineralization: Interaction of a Mad10-Derived Peptide with Magnetite Thin Films

Spin and orbital magnetism in 3dsystems

Real-time monitoring of calcium carbonate and cationic peptide deposition on carboxylate-SAM using a microfluidic SAW biosensor

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