@misc{peng_lewis_hoertz_glass_parsons_2012, title={Atomic layer deposition for electrochemical energy generation and storage systems}, volume={30}, ISSN={["0734-2101"]}, url={http://gateway.webofknowledge.com/gateway/Gateway.cgi?GWVersion=2&SrcAuth=ORCID&SrcApp=OrcidOrg&DestLinkType=FullRecord&DestApp=WOS_CPL&KeyUT=WOS:000298992800067&KeyUID=WOS:000298992800067}, DOI={10.1116/1.3672027}, abstractNote={Clean renewable energy sources (e.g., solar, wind, and hydro) offers the most promising solution to energy and environmental sustainability. On the other hand, owing to the spatial and temporal variations of renewable energy sources, and transportation and mobility needs, high density energy storage and efficient energy distribution to points of use is also critical. Moreover, it is challenging to scale up those processes in a cost-effective way. Electrochemical processes, including photoelectrochemical devices, batteries, fuel cells, super capacitors, and others, have shown promise for addressing many of the abovementioned challenges. Materials with designer properties, especially the interfacial properties, play critical role for the performance of those devices. Atomic layer deposition is capable of precise engineering material properties on atomic scale. In this review, we focus on the current state of knowledge of the applications, perspective and challenges of atomic layer deposition process on the electrochemical energy generation and storage devices and processes.}, number={1}, journal={JOURNAL OF VACUUM SCIENCE & TECHNOLOGY A}, author={Peng, Qing and Lewis, Jay S. and Hoertz, Paul G. and Glass, Jeffrey T. and Parsons, Gregory N.}, year={2012}, month={Jan} } @misc{stoner_glass_hooke_williams_1995, title={Nucleation enhancement for chemical vapor deposition of diamond}, volume={5397428}, publisher={Washington, DC: U.S. Patent and Trademark Office}, author={Stoner, B. R. and Glass, J. T. and Hooke, W. M. and Williams, B. E.}, year={1995} } @article{wolter_stoner_glass_ellis_buhaenko_jenkins_southworth_1993, title={Textured growth of diamond on silicon via insitu carburization and bias-enhanced nucleation}, volume={62}, number={11}, journal={Applied Physics Letters}, author={Wolter, S. D. and Stoner, B. R. and Glass, J. T. and Ellis, P. J. and Buhaenko, D. S. and Jenkins, C. E. and Southworth, P.}, year={1993}, pages={1215–1217} } @article{stoner_ma_wolter_glass_1992, title={Characterization of bias-enhanced nucleation of diamond on silicon by invacuo surface-analysis and transmission electron-microscopy}, volume={45}, number={19}, journal={Physical Review. B, Condensed Matter and Materials Physics}, author={Stoner, B. R. and Ma, G. H. M. and Wolter, S. D. and Glass, J. T.}, year={1992}, pages={11067–11084} } @article{stoner_glass_1992, title={Textured diamond growth on (100) beta-sic via microwave plasma chemical vapor-deposition}, volume={60}, number={6}, journal={Applied Physics Letters}, author={Stoner, B. R. and Glass, J. T.}, year={1992}, pages={698–700} } @article{shroder_nemanich_glass_1990, title={ANALYSIS OF THE COMPOSITE STRUCTURES IN DIAMOND THIN-FILMS BY RAMAN-SPECTROSCOPY}, volume={41}, ISSN={["2469-9969"]}, DOI={10.1103/physrevb.41.3738}, abstractNote={Diamond and diamondlike thin films produced by various chemical-vapor-deposition processes have been examined using Raman spectroscopy. These films exhibit features in the Raman spectra, suggesting that they are composites of crystalline and amorphous diamond and graphitic structures. The components of this composite structure that contribute to the Raman scattering are discussed in terms of ${\mathrm{sp}}^{2}$- and ${\mathrm{sp}}^{3}$-bonded structures. The use of Raman spectroscopy as a technique for estimating the ${\mathrm{sp}}^{2}$-to-${\mathrm{sp}}^{3}$ bonding ratio is considered. Powder composites of BN-diamond and graphite-diamond have been studied as a means of modeling the films, and a simple theoretical model of the Raman scattering from these samples is proposed. From these results it is shown that it is necessary to make assumptions about the domain size of the graphitic ${\mathrm{sp}}^{2}$ regions. It is found that the Raman scattering associated with ${\mathrm{sp}}^{2}$ bonding in the films is much stronger than that from single-crystalline or microcrystalline graphite structures. Shifts of the vibrational modes are also observed. The optical and vibrational properties of the ${\mathrm{sp}}^{2}$ component in the films implies a different atomic microstructure. A model of the ${\mathrm{sp}}^{2}$-bonding configurations in the films is proposed which may account for the observed features in the Raman spectra.}, number={6}, journal={PHYSICAL REVIEW B}, author={SHRODER, RE and NEMANICH, RJ and GLASS, JT}, year={1990}, month={Feb}, pages={3738–3745} } @article{nemanich_glass_lucovsky_shroder_1988, title={RAMAN-SCATTERING CHARACTERIZATION OF CARBON BONDING IN DIAMOND AND DIAMONDLIKE THIN-FILMS}, volume={6}, ISSN={["1520-8559"]}, DOI={10.1116/1.575297}, abstractNote={The atomic bonding configurations of carbon bonding in diamond and diamondlike thin films are explored using Raman scattering. The general aspects of Raman scattering from composites are presented. Effects are discussed due to crystalline or amorphous structures, large versus microcrystalline domains, and strong optical absorption and transparent regions. The Raman scattering from diamondlike films shows several features which are attributed to microcrystalline graphitelike structures which all originate from the same region in the sample. In contrast, the spectra of diamond films show features attributed to different components of a composite film. Components identified are crystalline diamond, and disordered and microcrystalline graphitic structures. The presence of precursor microcrystalline or amorphous diamond structures is also suggested.}, number={3}, journal={JOURNAL OF VACUUM SCIENCE & TECHNOLOGY A}, author={NEMANICH, RJ and GLASS, JT and LUCOVSKY, G and SHRODER, RE}, year={1988}, pages={1783–1787} }