Your search keyword '"Laura E. Slusher"' showing total 2 results

1. Short Communication: Room-Temperature Growth of Carbon Nanofibers From Iron-Encapsulated Dendritic Catalysts

Author

Dale J Lecaptain, Bradley D. Fahlman, Jeffery E. Raymond, Jason K. Vohs, Laura E. Slusher, Jonathan J. Brege, Steven J. Rozeveld, and Geoffrey L. Williams

Subjects

chemistry.chemical_classification, Materials science, Polymers and Plastics, Carbon nanofiber, chemistry.chemical_element, Electrochemistry, Decomposition, Catalysis, Electric arc, Hydrocarbon, Chemical engineering, chemistry, Impurity, Chemical Engineering (miscellaneous), Organic chemistry, Carbon

Abstract

Ordered carbonaceous growth typically requires high-energy methods such as arc discharge [1] or decomposition of hydrocarbon-based precursors using laser [2–4], plasma [3], or thermolytic techniques [4]. For the latter technique, temperature regimes on the order of 600–1000° C are most common, with a few recent reports citing lower temperatures using halogenated precursors [5–7], or through alkali-metal catalyzed transformation of bulk carbon allotropes [8,9]. Sailor etal. have reported the first growth of non-amorphous carbon deposits at room temperature [10]. However, their electrochemical synthesis did not produce nanostructural carbon; due to the absence of nanosized catalytic seeds, the diameters of their fibers were > 5μm, and contained copious amounts of Cl, H, N, and O impurities.

Published

2005

2. Facile Synthesis of Tin Oxide Nanoparticles Stabilized by Dendritic Polymers

Author

Laura E. Slusher, Robert L. Paddock, Andrew E. Richardson, Venkateswarlu Juttukonda, Dan R. Denomme, Jeffery E. Raymond, and Bradley D. Fahlman

Subjects

chemistry.chemical_classification, Stannate, Oxide, Ethyleneimine, Nanoparticle, chemistry.chemical_element, General Chemistry, Polymer, Tin oxide, Biochemistry, Catalysis, chemistry.chemical_compound, Colloid and Surface Chemistry, chemistry, Dendrimer, Polymer chemistry, Tin

Abstract

Tin(IV) oxide nanoparticles were synthesized via the reaction of carbon dioxide with stannate ions immobilized by dendritic polymers. For PAMAM and PPI dendrimer hosts, resultant nanoparticle diameters were 2.5-3 nm; 3-3.5 nm nanoparticles resulted from use of a poly(ethyleneimine) hyperbranched polymer. Our conditions represent the only precedent for SnO2 nanoparticulate growth using dendritic architectures, as well as a novel application for CO2 as a reactive gas for the controlled growth of metal oxide nanoparticles.

Published

2005