K
Krishna KC Data-verified
Affiliation confirmed via AI analysis of OpenAlex, ORCID, and web sources.
Researcher
unknown
1 h-index
4 pubs
9 cited
Research Areas
Biography and Research Information
OverviewAI-generated summary
Krishna KC's research focuses on the development and study of novel materials for energy conversion and environmental applications. His recent work includes the creation of non-precious electrocatalysts derived from nanocellulose, dopamine, and cobalt complexes for enhanced oxygen reduction reactions. He has also investigated low-cost synthesis methods for tungsten oxide nanostructures using resistive hot wire oxidation and explored the tunable properties of WO₂.₉ for improved photocatalytic efficiency in copper oxide-based Z-scheme systems. Further research has examined Z-scheme tungsten copper oxide for photocatalytic water splitting. KC collaborates with Fumiya Watanabe, Janak Paudel, and John Nichols, all at the University of Arkansas at Little Rock, with shared publications across their projects. His scholarship metrics include an h-index of 1, with 4 total publications and 8 total citations.
Metrics
- h-index: 1
- Publications: 4
- Citations: 9
Selected Publications
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Tunable WO <sub>2.9</sub> Volume for Boosted Photocatalytic Efficiency in Cu <sub>2</sub> O Based Z-Scheme Systems (2025)
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<i>Z</i>-Scheme Tungsten Copper Oxide for Photocatalytic Water Splitting (2025)
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A single-step low-cost synthesis of tungsten oxide nanostructures by resistive hot wire oxidation (2024)
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Exploring Enhanced Oxygen Reduction Reactions: A Study on Nanocellulose, Dopamine, and Cobalt Complex-Derived Non-Precious Electrocatalyst (2024)
Collaboration Network
Top Collaborators
Fumiya Watanabe
University of Arkansas at Little Rock
4 shared publications
In database
- Exploring Enhanced Oxygen Reduction Reactions: A Study on Nanocellulose, Dopamine, and Cobalt Complex-Derived Non-Precious Electrocatalyst
- A single-step low-cost synthesis of tungsten oxide nanostructures by resistive hot wire oxidation
- <i>Z</i>-Scheme Tungsten Copper Oxide for Photocatalytic Water Splitting
- Tunable WO <sub>2.9</sub> Volume for Boosted Photocatalytic Efficiency in Cu <sub>2</sub> O Based Z-Scheme Systems
Santiago J. Dopico
University of Arkansas at Little Rock
3 shared publications
In database
- A single-step low-cost synthesis of tungsten oxide nanostructures by resistive hot wire oxidation
- <i>Z</i>-Scheme Tungsten Copper Oxide for Photocatalytic Water Splitting
- Tunable WO <sub>2.9</sub> Volume for Boosted Photocatalytic Efficiency in Cu <sub>2</sub> O Based Z-Scheme Systems
Janak Paudel
University of Arkansas at Little Rock
3 shared publications
In database
- A single-step low-cost synthesis of tungsten oxide nanostructures by resistive hot wire oxidation
- <i>Z</i>-Scheme Tungsten Copper Oxide for Photocatalytic Water Splitting
- Tunable WO <sub>2.9</sub> Volume for Boosted Photocatalytic Efficiency in Cu <sub>2</sub> O Based Z-Scheme Systems
J. B. Nichols
University of Arkansas at Little Rock (US)
3 shared publications
- A single-step low-cost synthesis of tungsten oxide nanostructures by resistive hot wire oxidation
- <i>Z</i>-Scheme Tungsten Copper Oxide for Photocatalytic Water Splitting
- Tunable WO <sub>2.9</sub> Volume for Boosted Photocatalytic Efficiency in Cu <sub>2</sub> O Based Z-Scheme Systems
Marvin M. Bonney
University of Arkansas at Little Rock
2 shared publications
In database
- A single-step low-cost synthesis of tungsten oxide nanostructures by resistive hot wire oxidation
- <i>Z</i>-Scheme Tungsten Copper Oxide for Photocatalytic Water Splitting
Andrew Kingston
University of Arkansas at Little Rock
2 shared publications
In database
- A single-step low-cost synthesis of tungsten oxide nanostructures by resistive hot wire oxidation
- <i>Z</i>-Scheme Tungsten Copper Oxide for Photocatalytic Water Splitting
Anshu Sharma
2 shared publications
In database
- <i>Z</i>-Scheme Tungsten Copper Oxide for Photocatalytic Water Splitting
- Tunable WO <sub>2.9</sub> Volume for Boosted Photocatalytic Efficiency in Cu <sub>2</sub> O Based Z-Scheme Systems
Md Mohsin Patwary
University of Arkansas at Little Rock
1 shared publication
In database
- Exploring Enhanced Oxygen Reduction Reactions: A Study on Nanocellulose, Dopamine, and Cobalt Complex-Derived Non-Precious Electrocatalyst
Shanzida Haque
University of Arkansas at Little Rock
1 shared publication
In database
- Exploring Enhanced Oxygen Reduction Reactions: A Study on Nanocellulose, Dopamine, and Cobalt Complex-Derived Non-Precious Electrocatalyst
Peter Szwedo
University of Arkansas at Little Rock
1 shared publication
In database
- Exploring Enhanced Oxygen Reduction Reactions: A Study on Nanocellulose, Dopamine, and Cobalt Complex-Derived Non-Precious Electrocatalyst
G. I. Hasan
University of Arkansas at Little Rock
1 shared publication
In database
- Exploring Enhanced Oxygen Reduction Reactions: A Study on Nanocellulose, Dopamine, and Cobalt Complex-Derived Non-Precious Electrocatalyst
Raja Shekhar Kondrapolu
University of Arkansas at Little Rock
1 shared publication
In database
- Exploring Enhanced Oxygen Reduction Reactions: A Study on Nanocellulose, Dopamine, and Cobalt Complex-Derived Non-Precious Electrocatalyst
Daoyuan Wang
University of Arkansas at Pine Bluff (US)
1 shared publication
- Exploring Enhanced Oxygen Reduction Reactions: A Study on Nanocellulose, Dopamine, and Cobalt Complex-Derived Non-Precious Electrocatalyst
Anindya Ghosh
University of Arkansas at Little Rock (US)
1 shared publication
- Exploring Enhanced Oxygen Reduction Reactions: A Study on Nanocellulose, Dopamine, and Cobalt Complex-Derived Non-Precious Electrocatalyst
G.M. Ibrahim
University of Alkafeel (IQ)
1 shared publication
- A single-step low-cost synthesis of tungsten oxide nanostructures by resistive hot wire oxidation
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