Conductive Organic-inorganic Nanostructures
Dendritic structures assembled via connections between mineralizing KCl crystallites initiated by pH-triggered self-assembly of peptide materials was demonstrated. Connected structures were found to be the most important factor for producing highly conductive nanowire assemblies that showed conductivity comparable to that of a metal (~1800 S/cm). Measurements of conductivity over time and conductivity quenching by ammonia suggested the conductivity of these dendritic networks was derived from proton doping of the central π-electron units in strong acid environment and was facilitated by closely spaced chromophores leading to facile π-electron transfer along the interconnected dendritic pathways. It is expected that more electrically relevant materials may be able to be templated through this approach.
J. Tovar and H. Katz (Johns Hopkins U.)
Dendritic structures assembled via connections between mineralizing KCl crystallites initiated by pH-triggered self-assembly of peptide materials was demonstrated. Connected structures were found to be the most important factor for producing highly conductive nanowire assemblies that showed conductivity comparable to that of a metal (~1800 S/cm). Measurements of conductivity over time and conductivity quenching by ammonia suggested the conductivity of these dendritic networks was derived from proton doping of the central π-electron units in strong acid environment and was facilitated by closely spaced chromophores leading to facile π-electron transfer along the interconnected dendritic pathways. It is expected that more electrically relevant materials may be able to be templated through this approach.