Joseph Joel Muhanga Data-verified
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Researcher
unknown
Research Areas
Biography and Research Information
OverviewAI-generated summary
Joseph Joel Muhanga's research investigates the properties and applications of ultra-thin metal oxide films and nanostructures. His work includes characterizing the stability of these materials in catalytic processes, such as non-thermal plasma CO2 reduction reactions. Muhanga also explores the use of core-shell TiO2 nanostructures for monolithic light concentration, templated by polymer colloidal monolayers. His publications also address the development of effective medium approximations for calculating the refractive index of stratified metal oxide composites synthesized through atomic layer deposition. Muhanga has collaborated with researchers at the University of Arkansas at Fayetteville, including Robert H. Coridan and Samuel K. Conlin, with whom he shares multiple publications.
Metrics
- h-index: 2
- Publications: 8
- Citations: 6
Selected Publications
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Effective medium approximation for the refractive index of stratified metal oxide composites synthesized by atomic layer deposition (2026)
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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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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)
Collaboration Network
Top Collaborators
- Monolithic light concentration by core–shell TiO <sub>2</sub> nanostructures templated by monodisperse polymer colloidal monolayers
- 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 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
- Supplemental Information Numbers 1-8
Showing 5 of 8 shared publications
- Monolithic light concentration by core–shell TiO <sub>2</sub> nanostructures templated by monodisperse polymer colloidal monolayers
- 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 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
- 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
- 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 CO <sub>2</sub> reduction reactions
- Characterizing the Stability of Ultra-Thin Metal Oxide Catalyst Films in Non-thermal Plasma CO2 Reduction Reactions
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