0000000000542177

AUTHOR

Konstantinos D. Demadis

showing 3 related works from this author

Pleiotropic Role of Recombinant Silaffin-Like Cationic Polypeptide P5S3: Peptide-Induced Silicic Acid Stabilization, Silica Formation and Inhibition …

2016

Silica-mineralizing organisms such as diatoms manage several aspects of silica chemistry when polymerizing monomeric silicic acid into amorphous silica. Silicic acid is undersaturated in the diatoms’ habitats and mechanisms of enrichment and prevention of uncontrolled mineralization are not well understood. Diatom-biosilica is associated with organic compounds, including polycationic, post-translationally modified peptides termed silaffins, which induce the condensation of silicic acid under supersaturated conditions. Here, we report the pleiotropic action of the designed silaffin-like peptide P5S3, which (i) stabilizes 4–8x silicic acid (in supersaturated conditions of 8.3 mm), (ii) decele…

chemistry.chemical_classificationPrecipitation (chemistry)Inorganic chemistryCationic polymerizationPeptide02 engineering and technologyGeneral Chemistryrespiratory system010402 general chemistry021001 nanoscience & nanotechnology01 natural sciences0104 chemical sciencesAmino acidchemistry.chemical_compoundHydrolysischemistryBiomimetic synthesisPolymer chemistrySilicic acid0210 nano-technologyDissolutionChemistrySelect
researchProduct

Structure-Dependent Dissolution and Restructuring of Calcite Surfaces by Organophosphonates

2017

Organophosphonates are well-known to strongly interact with the surfaces of various minerals, such as brucite, gypsum, and barite. In this work, we study the influence of six systematically varied organophosphonate molecules (tetraphosphonates and diphosphonates) on the dissolution process of the (10.4) surface of calcite. In order to pursue a systematic study, we have selected organophosphonates that exhibit similar structural features, but also systematic architectural differences. The effect of this class of additives on the dissolution process of the calcite (10.4) surface is evaluated using in situ dynamic atomic force microscopy. For all of the six organophosphonate derivatives, we ob…

CalciteGypsumAtomic force microscopyBruciteDiphosphonates02 engineering and technologyGeneral Chemistryengineering.material010402 general chemistry021001 nanoscience & nanotechnologyCondensed Matter Physics53001 natural sciences0104 chemical scienceschemistry.chemical_compoundCrystallographychemistryChemical engineeringengineeringMoleculeGeneral Materials ScienceOrganophosphonates0210 nano-technologyDissolutionCrystal Growth & Design
researchProduct

Cover Picture: Pleiotropic Role of Recombinant Silaffin-Like Cationic Polypeptide P5S3: Peptide-Induced Silicic Acid Stabilization, Silica Formation …

2016

chemistry.chemical_classificationMaterials scienceCationic polymerizationPeptideGeneral Chemistrylaw.inventionchemistry.chemical_compoundchemistrylawBiomimetic synthesisRecombinant DNAOrganic chemistryCover (algebra)Silicic acidDissolutionChemistrySelect
researchProduct