R
Ronald Gronsky
Researcher at University of California, Berkeley
Publications - 259
Citations - 7224
Ronald Gronsky is an academic researcher from University of California, Berkeley. The author has contributed to research in topics: High-resolution transmission electron microscopy & Thin film. The author has an hindex of 41, co-authored 259 publications receiving 7021 citations. Previous affiliations of Ronald Gronsky include University of California & Center for Advanced Materials.
Papers
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Journal ArticleDOI
Synthesis of B x C y N z nanotubules
Z. Weng-Sieh,Z. Weng-Sieh,K. Cherrey,K. Cherrey,Nasreen G. Chopra,Nasreen G. Chopra,Xavier Blase,Xavier Blase,Yoshiyuki Miyamoto,Yoshiyuki Miyamoto,Angel Rubio,Angel Rubio,Marvin L. Cohen,Marvin L. Cohen,Steven G. Louie,Steven G. Louie,Alex Zettl,Alex Zettl,Ronald Gronsky,Ronald Gronsky +19 more
TL;DR: In this article, Arc-discharge methods were used to produce stable nanotubule structures identified by high-resolution transmission-electron microscopy, and local electron-energy-loss spectroscopy of {ital K}-edge absorptions for B, C and N atoms was used to determine the atomic compositions of individual tubules.
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Synthesis, characterization, and properties of nanophase TiO 2
TL;DR: In this paper, nanophase compacts with average initial grain sizes of 12 nm were found to densify rapidly above 500 °C, with only a small increase in grain size.
Journal ArticleDOI
Surface, interface, and thin-film magnetism
L. M. Falicov,Daniel T. Pierce,S. D. Bader,Ronald Gronsky,Kristl B. Hathaway,Herbert Hopster,David N. Lambeth,Stuart S. P. Parkin,G. A. Prinz,M. B. Salamon,Ivan K. Schuller,R. H. Victora +11 more
TL;DR: A comprehensive review and state of the art in the field of surface, interface, and thin-film magnetism is presented in this article, where the current status and issues in the area of material growth techniques and physical properties, characterization methods, and theoretical methods and ideas are reviewed.
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Electrodeposition of Ordered Bi2Te3 Nanowire Arrays
Amy L. Prieto,Melissa S. Sander,Marisol Martín-González,Ronald Gronsky,Timothy D. Sands,Angelica M. Stacy +5 more
TL;DR: Porous alumina is a good choice for a template because the pore diameters are easily adjusted to sizes enabling quantum confinement, and is currently the most efficient thermoelectric material at 25°C, and a good target material for thermoeLECTric nanowires.