Santiago J. Dopico Data-verified
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Researcher
grad_student
Research Areas
Biography and Research Information
OverviewAI-generated summary
Santiago J. Dopico, a graduate student at the University of Arkansas at Little Rock, focuses his research on advanced photocatalysis techniques, particularly employing copper-based nanomaterials. His work investigates the electronic and structural properties of oxides, with an emphasis on transition metal oxide nanomaterials for applications in advanced memory and neural computing. Dopico's recent work includes the development of a single-step, low-cost synthesis method for tungsten oxide nanostructures using resistive hot wire oxidation. Further research explores the photocatalytic efficiency of Cu<sub>2</sub>O-based Z-scheme systems through tunable WO<sub>2.9</sub> volumes and the application of Z-scheme tungsten copper oxide in photocatalytic water splitting.
Metrics
- h-index: 1
- Publications: 3
- Citations: 2
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)
Collaboration Network
Top Collaborators
- 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
- 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
- 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
- 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
- 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
- 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
- <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
- A single-step low-cost synthesis of tungsten oxide nanostructures by resistive hot wire oxidation
- A single-step low-cost synthesis of tungsten oxide nanostructures by resistive hot wire oxidation
- 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
- <i>Z</i>-Scheme Tungsten Copper Oxide for Photocatalytic Water Splitting