Your search keyword '"Baker, Jon G."' showing total 4 results

1. The Influence of Ozone: Superstoichiometric Oxygen in Atomic Layer Deposition of Fe2O3 Using tert‐Butylferrocene and O3.

Author

Schneider, Joel R., Baker, Jon G., and Bent, Stacey F.

Subjects

ATOMIC layer deposition, OXYGEN, OZONE, FERRIC oxide, IRON ores, HEMATITE, IRON oxides, METALLIC oxides

Abstract

Understanding the chemical mechanisms at play in atomic layer deposition (ALD) is critical for effective process development and expansion of ALD into more complex classes of materials. In this work, a mechanistic study of iron oxide deposited by ALD using tert‐butylferrocene and ozone as reactants is performed. Iron oxide ALD using ozone is a useful model system for mechanistic studies due to the prevalence of ozone‐based ALD processes and the uses of iron oxide in ternary and quaternary metal oxides. Results show that saturation conditions require significantly greater exposures of both reactants than is typically reported in the literature, and growths per cycle of greater than one monolayer of Fe2O3 per cycle are observed and explained. A growth mechanism is proposed whereby increased ozone exposure results in uptake of superstoichiometric oxygen into the film. X‐ray characterizations reveal the presence of excess oxygen stored near the surface of films deposited with larger ozone exposures and show that increased ozone exposures cause crystalline domain rearrangement and conversion of the film from the γ‐maghemite phase to the α‐hematite phase. The mechanism described here has implications for the wider class of ozone‐based ALD processes, and potential applications of this growth phenomenon are discussed. [ABSTRACT FROM AUTHOR]

Published

2020

2. A Combined Theory‐Experiment Analysis of the Surface Species in Lithium‐Mediated NH3 Electrosynthesis.

Author

Schwalbe, Jay A., Statt, Michael J., Chosy, Cullen, Singh, Aayush R., Rohr, Brian A., Nielander, Adam C., Andersen, Suzanne Z., McEnaney, Joshua M., Baker, Jon G., Jaramillo, Thomas F., Norskov, Jens K., and Cargnello, Matteo

Subjects

SURFACE analysis, HABER-Bosch process, ELECTROSYNTHESIS, HYDROGEN evolution reactions, SUPERIONIC conductors, SOLID state batteries, LITHIUM hydride

Abstract

Electrochemical processes for ammonia synthesis could potentially replace the high temperature and pressure conditions of the Haber‐Bosch process, with voltage offering a pathway to distributed fertilizer production that leverages the rapidly decreasing cost of renewable electricity. However, nitrogen is an unreactive molecule and the hydrogen evolution reaction presents a major selectivity challenge. An electrode of electrodeposited lithium in tetrahydrofuran solvent overcomes both problems by providing a surface that easily reacts with nitrogen and by limiting the access of protons with a nonaqueous electrolyte. Under these conditions, we measure relatively high faradaic efficiencies (ca. 10 %) and rates (0.1 mA cm−2) toward NH3. We observe the development of a solid electrolyte interface layer as well as the accumulation of lithium and lithium‐containing species. Detailed DFT studies suggest lithium nitride and hydride to be catalytically active phases given their thermodynamic and kinetic stability relative to metallic lithium under reaction conditions and the fast diffusion of nitrogen in lithium. [ABSTRACT FROM AUTHOR]

Published

2020

3. Front Cover: A Combined Theory‐Experiment Analysis of the Surface Species in Lithium‐Mediated NH3 Electrosynthesis (ChemElectroChem 7/2020).

Author

Schwalbe, Jay A., Statt, Michael J., Chosy, Cullen, Singh, Aayush R., Rohr, Brian A., Nielander, Adam C., Andersen, Suzanne Z., McEnaney, Joshua M., Baker, Jon G., Jaramillo, Thomas F., Norskov, Jens K., and Cargnello, Matteo

Subjects

SURFACE analysis, ELECTROSYNTHESIS, ATMOSPHERIC ammonia, ATMOSPHERIC temperature, SPECIES

Abstract

Keywords: ammonia; catalysis; density functional calculations; electrochemistry; Haber-Bosch EN ammonia catalysis density functional calculations electrochemistry Haber-Bosch 1509 1509 1 04/20/20 20200401 NES 200401 B The Front Cover b shows the idealized lithium-containing species on an electrocatalyst surface for the reduction of nitrogen to ammonia at atmospheric pressure and temperature. The nitrogen activation occurs in non-aqueous electrolytes to achieve high faradaic efficiency on a complex reactive surface. Ammonia, catalysis, density functional calculations, electrochemistry, Haber-Bosch. [Extracted from the article]

Published

2020

4. Structurally Stable Manganese Alkoxide Films Grown by Hybrid Molecular Layer Deposition for Electrochemical Applications.

Author

Bergsman, David S., Baker, Jon G., Closser, Richard G., MacIsaac, Callisto, Lillethorup, Mie, Strickler, Alaina L., Azarnouche, Laurent, Godet, Ludovic, and Bent, Stacey F.

Subjects

*MANGANESE, *ATOMIC layer deposition, *OXYGEN evolution reactions, *CARBOXYLATES, *ANNEALING of metals, *THIN films, *ETHYLENE glycol, *ELECTRODE reactions

Abstract

Hybrid molecular layer deposition (MLD) has significant potential for the creation of ultrathin electrochemically active materials, due to its ability to combine organic and inorganic species to modulate film properties. However, only a limited number of hybrid MLD processes are demonstrated with electrochemically relevant elements, such as manganese. Here, a "manganicone" manganese hybrid MLD chemistry is developed using the precursors bis(ethylcyclopentadienyl)manganese and ethylene glycol. The resulting manganese alkoxide coordination networks are shown to have many interesting properties, including the ability to seamlessly fill high aspect ratio vias and the chemical conversion into manganese carboxylate in air over several hours at room temperature. Linear, self‐saturating growth is reported. Importantly, hybrid manganicone films annealed to 480 °C in air demonstrate a greater stability to restructuring during electrochemical testing than their inorganic counterparts grown by atomic layer deposition, without reducing the activity of the reactive sites on the manganese surface. Thus, hybrid manganese films grown by MLD have significant promise for use as catalysts for the oxygen evolution reaction and as electrodes in thin film batteries. [ABSTRACT FROM AUTHOR]

Published

2019