Journal
NANO LETTERS
Volume 9, Issue 6, Pages 2316-2321Publisher
AMER CHEMICAL SOC
DOI: 10.1021/nl900528q
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- Office of Naval Research
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Subambient thermal decomposition of ruthenium tetroxide from nonaqueous solution onto porous SiO2 substrates creates 2-3 nm thick coatings of RuO2 that cover the convex silica walls comprising the open, porous structure. The physical properties of the resultant self-wired nanoscale ruthenia significantly differ depending on the nature of the porous support. Previously reported RuO2-modified SiO2 aerogels display electron conductivity of 5 x 10(-4) S cm(-1) (as normalized to the geometric factor of the insulating substrate, not the conducting ruthenia phase), whereas RuO2-modified silica filter paper at similar to 5 wt % RuO2 exhibits similar to 0.5 S cm(-1). Electron conduction through the ruthenia phase as examined from -160 to 260 degrees C requires minimal activation energy, only 8 meV, from 20 to 260 degrees C. The RuO2(SiO2) fiber membranes are electrically addressable, capable of supporting fast electron-transfer reactions, express an electrochemical surface area of similar to 90 m(2) g(-1) RuO2, and exhibit energy storage in which 90% of the total electron-proton charge is stored at the outer surface of the ruthenia phase. The electrochemical capacitive response indicates that the nanocrystalline RuO2 coating can be considered to be a single-unit-thick layer of the conductive oxide, as physically stabilized by the supporting silica fiber.
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