D
David N. Parette Data-verified
Affiliation confirmed via AI analysis of OpenAlex, ORCID, and web sources.
Research Professional II
unknown
3 h-index
6 pubs
10 cited
Research Areas
Links
Biography and Research Information
OverviewAI-generated summary
David N. Parette's research focuses on the characterization of catalysts used in the plasma reduction of CO<sub>2</sub>. His recent work investigates the function and transformations of atomic layer deposition-synthesized catalysts, as well as the stability of ultra-thin metal oxide catalyst films in non-thermal plasma CO<sub>2</sub> reduction reactions. Parette has also explored the sustaining mechanisms of redox-magnetohydrodynamics (R-MHD) microfluidics through the switching of permanent magnets. He collaborates with several researchers at the University of Arkansas at Fayetteville, including Robert H. Coridan and Samuel K. Conlin, with whom he has multiple shared publications. Parette's scholarly output includes 6 publications and he has an h-index of 3 with 10 total citations.
Metrics
- h-index: 3
- Publications: 6
- Citations: 10
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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Sustaining redox-magnetohydrodynamics (R-MHD) microfluidics by switching oppositely-polarized permanent magnets: Synchronized activation and automation (2021)
Collaboration Network
Top Collaborators
Samuel K. Conlin
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
Robert H. Coridan
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
Hamed Mehrabi
University of Arkansas at Fayetteville
2 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 Catalyst Function and Transformations in the Plasma Reduction of CO 2 on Atomic Layer Deposition-Synthesized Catalysts
Joseph Joel Muhanga
University of Arkansas at Fayetteville
2 shared publications
In database
- Characterizing the stability of ultra-thin metal oxide catalyst films in non-thermal plasma CO <sub>2</sub> reduction reactions
- Characterizing the Stability of Ultra-Thin Metal Oxide Catalyst Films in Non-thermal Plasma CO2 Reduction Reactions
Foysal Z. Khan
University of Arkansas at Fayetteville
1 shared publication
In database
- Sustaining redox-magnetohydrodynamics (R-MHD) microfluidics by switching oppositely-polarized permanent magnets: Synchronized activation and automation
Miguel A. Abrego Tello
University of Arkansas at Fayetteville (US)
1 shared publication
- Sustaining redox-magnetohydrodynamics (R-MHD) microfluidics by switching oppositely-polarized permanent magnets: Synchronized activation and automation
Ingrid Fritsch
University of Arkansas at Fayetteville (US)
1 shared publication
- Sustaining redox-magnetohydrodynamics (R-MHD) microfluidics by switching oppositely-polarized permanent magnets: Synchronized activation and automation
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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