S
Samuel K. Conlin Data-verified
Affiliation confirmed via AI analysis of OpenAlex, ORCID, and web sources.
Researcher
faculty
3 h-index
12 pubs
56 cited
Research Areas
Links
Biography and Research Information
OverviewAI-generated summary
Samuel K. Conlin's research focuses on electrocatalysis and materials science, particularly in the context of solar-to-fuel electrolysis and carbon dioxide reduction. His work investigates the characterization of catalyst function and transformations under various conditions, including low cell potentials and non-thermal plasma environments. Conlin has published research on the electrochemical control of surface morphology and functional properties of copper surfaces, as well as the stability of metal oxide catalyst films in plasma reactions. He has also explored monolithic light concentration using core-shell TiO2 nanostructures. Conlin's scholarly activity includes 12 publications with 54 citations and an h-index of 3. He has a history of collaboration with other University of Arkansas faculty, including Robert H. Coridan, Hamed Mehrabi, Joseph Joel Muhanga, and David N. Parette, with whom he shares multiple publications.
Metrics
- h-index: 3
- Publications: 12
- Citations: 56
Selected Publications
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Characterizing the stability of ultra-thin metal oxide catalyst films in non-thermal plasma CO <sub>2</sub> reduction reactions (2024)
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Characterizing the Stability of Ultra-Thin Metal Oxide Catalyst Films in Non-thermal Plasma CO2 Reduction Reactions (2024)
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Characterizing catalyst function and transformations in the plasma reduction of CO<sub>2</sub> on atomic layer deposition-synthesized catalysts (2024)
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Characterizing Catalyst Function and Transformations in the Plasma Reduction of CO 2 on Atomic Layer Deposition-Synthesized Catalysts (2024)
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Modular Solar-to-Fuel Electrolysis at Low Cell Potentials Enabled by Glycerol Electrooxidation and a Bipolar Membrane Separator (2023)
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Modular solar-to-fuels electrolysis at low cell potentials enabled by glycerol electrooxidation and a bipolar membrane separator (2023)
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Modular solar-to-fuels electrolysis at low cell potentials enabled by glycerol electrooxidation and a bipolar membrane separator (2023)
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Monolithic light concentration by core–shell TiO <sub>2</sub> nanostructures templated by monodisperse polymer colloidal monolayers (2023)
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Monolithic light concentration by core-shell TiO2 nanostructures templated by monodisperse polymer colloidal monolayers (2023)
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Electrochemical Control of the Morphology and Functional Properties of Hierarchically Structured, Dendritic Cu Surfaces (2022)
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Electrochemical control of the morphology and functional properties of hierarchically structured, dendritic Cu surfaces (2022)
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Characterizing Sustained Solar-to-Hydrogen Electrocatalysis at Low Cell Potentials Enabled by Crude Glycerol Oxidation (2022)
Collaboration Network
Top Collaborators
Robert H. Coridan
University of Arkansas at Fayetteville
12 shared publications
In database
- Characterizing Sustained Solar-to-Hydrogen Electrocatalysis at Low Cell Potentials Enabled by Crude Glycerol Oxidation
- Electrochemical Control of the Morphology and Functional Properties of Hierarchically Structured, Dendritic Cu Surfaces
- Characterizing catalyst function and transformations in the plasma reduction of CO<sub>2</sub> on atomic layer deposition-synthesized catalysts
- Characterizing the stability of ultra-thin metal oxide catalyst films in non-thermal plasma CO<sub>2</sub> reduction reactions
- Electrochemical control of the morphology and functional properties of hierarchically structured, dendritic Cu surfaces
Showing 5 of 12 shared publications
Hamed Mehrabi
University of Arkansas at Fayetteville
10 shared publications
In database
- Characterizing Sustained Solar-to-Hydrogen Electrocatalysis at Low Cell Potentials Enabled by Crude Glycerol Oxidation
- Electrochemical Control of the Morphology and Functional Properties of Hierarchically Structured, Dendritic Cu Surfaces
- Characterizing catalyst function and transformations in the plasma reduction of CO<sub>2</sub> on atomic layer deposition-synthesized catalysts
- Electrochemical control of the morphology and functional properties of hierarchically structured, dendritic Cu surfaces
- Monolithic light concentration by core–shell TiO <sub>2</sub> nanostructures templated by monodisperse polymer colloidal monolayers
Showing 5 of 10 shared publications
Zebulon G. Schichtl
University of Arkansas at Fayetteville (US)
4 shared publications
- Characterizing Sustained Solar-to-Hydrogen Electrocatalysis at Low Cell Potentials Enabled by Crude Glycerol Oxidation
- Modular Solar-to-Fuel Electrolysis at Low Cell Potentials Enabled by Glycerol Electrooxidation and a Bipolar Membrane Separator
- Modular solar-to-fuels electrolysis at low cell potentials enabled by glycerol electrooxidation and a bipolar membrane separator
- Modular solar-to-fuels electrolysis at low cell potentials enabled by glycerol electrooxidation and a bipolar membrane separator
Joseph Joel Muhanga
University of Arkansas at Fayetteville
4 shared publications
In database
- Characterizing the stability of ultra-thin metal oxide catalyst films in non-thermal plasma CO<sub>2</sub> reduction reactions
- Monolithic light concentration by core–shell TiO <sub>2</sub> nanostructures templated by monodisperse polymer colloidal monolayers
- Monolithic light concentration by core-shell TiO2 nanostructures templated by monodisperse polymer colloidal monolayers
- Characterizing the Stability of Ultra-Thin Metal Oxide Catalyst Films in Non-thermal Plasma CO2 Reduction Reactions
David N. Parette
University of Arkansas at Fayetteville
4 shared publications
In database
- Characterizing catalyst function and transformations in the plasma reduction of CO<sub>2</sub> on atomic layer deposition-synthesized catalysts
- Characterizing the stability of ultra-thin metal oxide catalyst films in non-thermal plasma CO<sub>2</sub> reduction reactions
- Characterizing Catalyst Function and Transformations in the Plasma Reduction of CO 2 on Atomic Layer Deposition-Synthesized Catalysts
- Characterizing the Stability of Ultra-Thin Metal Oxide Catalyst Films in Non-thermal Plasma CO2 Reduction Reactions
Thomas I. Hollis
University of Arkansas at Fayetteville
2 shared publications
In database
- Electrochemical Control of the Morphology and Functional Properties of Hierarchically Structured, Dendritic Cu Surfaces
- Electrochemical control of the morphology and functional properties of hierarchically structured, dendritic Cu surfaces
Johanna Nelson Weker
SLAC National Accelerator Laboratory (US)
2 shared publications
- Electrochemical Control of the Morphology and Functional Properties of Hierarchically Structured, Dendritic Cu Surfaces
- Electrochemical control of the morphology and functional properties of hierarchically structured, dendritic Cu surfaces
Rachel Cherry
University of Arkansas at Fayetteville
2 shared publications
In database
- Monolithic light concentration by core–shell TiO <sub>2</sub> nanostructures templated by monodisperse polymer colloidal monolayers
- Monolithic light concentration by core-shell TiO2 nanostructures templated by monodisperse polymer colloidal monolayers
Adam C. Nielander
SLAC National Accelerator Laboratory (US)
1 shared publication
- Characterizing Sustained Solar-to-Hydrogen Electrocatalysis at Low Cell Potentials Enabled by Crude Glycerol Oxidation
Brayley Gattis
1 shared publication
- Electrochemical control of the morphology and functional properties of hierarchically structured, dendritic Cu surfaces
Brayley S. Gattis
University of Arkansas at Fayetteville (US)
1 shared publication
- Electrochemical Control of the Morphology and Functional Properties of Hierarchically Structured, Dendritic Cu Surfaces
Eva N. Nichols
University of British Columbia (CA)
1 shared publication
- Characterizing Catalyst Function and Transformations in the Plasma Reduction of CO 2 on Atomic Layer Deposition-Synthesized Catalysts
Eva M. Nichols
University of British Columbia (CA)
1 shared publication
- Characterizing catalyst function and transformations in the plasma reduction of CO<sub>2</sub> on atomic layer deposition-synthesized catalysts
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