Emad Badradeen Data-verified
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Research Assistant Professor-Faculty
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Biography and Research Information
OverviewAI-generated summary
Emad Badradeen's research focuses on the synthesis and characterization of nanomaterials for various applications, including antibacterial surfaces and light-emitting devices. He has investigated methods for nanostructuring aluminum foil surfaces through steam treatment to enhance their antibacterial properties. His work also extends to halide perovskite-polymer composite films, exploring their potential for stable and bright light-emitting devices. Badradeen has studied the influence of substrate location and temperature on the growth of ZnO nanorods synthesized by hot water treatment, and determined the solid surface energy of tellurium dioxide.
He is involved in significant federal grant initiatives, serving as Principal Investigator (PI) on a $400,000 NSF grant for "Collaborative Research: EPIIC: Bolstering University Infrastructure for Leading Development (BUILD)" and as Co-PI on a $5,000,000 NSF grant for "ExpandQISE: Track 2: QuAPB, Expanding Quantum Research and Education at the University of Arkansas at Pine Bluff." These grants underscore his engagement in developing research infrastructure and expanding quantum research and education.
Badradeen's research network includes collaborations with researchers from the University of Arkansas at Little Rock, such as Tansel Karabacak, S. M. Sayem, Shawn E. Bourdo, and Nawab Ali, with whom he has co-authored multiple publications. His scholarship metrics include an h-index of 6, with 13 total publications and 99 total citations.
Metrics
- h-index: 6
- Publications: 13
- Citations: 101
Selected Publications
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Halide perovskite-polymer composite film for bright and stable light-emitting devices (2025)
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Influence of Substrate Location and Temperature Variation on the Growth of ZnO Nanorods Synthesized by Hot Water Treatment (2024)
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Determination of the solid surface energy of tellurium dioxide (2024)
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Correction: Enhancing antibacterial property of aluminum foil by nanostructuring its surface through a steam treatment (2023)
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Enhancing antibacterial property of aluminum foil by nanostructuring its surface through a steam treatment (2023)
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Core-Shell Electrocatalysts with Nanocolumnar Pt Thin Film Shell on Carbon Support Core for Polymer Electrolyte Membrane Fuel Cells (2022)
Federal Grants 2 $5,400,000 total
Collaborative Research: EPIIC: Bolstering University Infrastructure for Leading Development (BUILD)
Collaboration Network
Top Collaborators
- Enhancing antibacterial property of aluminum foil by nanostructuring its surface through a steam treatment
- Influence of Substrate Location and Temperature Variation on the Growth of ZnO Nanorods Synthesized by Hot Water Treatment
- Correction: Enhancing antibacterial property of aluminum foil by nanostructuring its surface through a steam treatment
- Core-Shell Electrocatalysts with Nanocolumnar Pt Thin Film Shell on Carbon Support Core for Polymer Electrolyte Membrane Fuel Cells
- Enhancing antibacterial property of aluminum foil by nanostructuring its surface through a steam treatment
- Influence of Substrate Location and Temperature Variation on the Growth of ZnO Nanorods Synthesized by Hot Water Treatment
- Correction: Enhancing antibacterial property of aluminum foil by nanostructuring its surface through a steam treatment
- Influence of Substrate Location and Temperature Variation on the Growth of ZnO Nanorods Synthesized by Hot Water Treatment
- Core-Shell Electrocatalysts with Nanocolumnar Pt Thin Film Shell on Carbon Support Core for Polymer Electrolyte Membrane Fuel Cells
- Enhancing antibacterial property of aluminum foil by nanostructuring its surface through a steam treatment
- Correction: Enhancing antibacterial property of aluminum foil by nanostructuring its surface through a steam treatment
- Enhancing antibacterial property of aluminum foil by nanostructuring its surface through a steam treatment
- Correction: Enhancing antibacterial property of aluminum foil by nanostructuring its surface through a steam treatment
- Enhancing antibacterial property of aluminum foil by nanostructuring its surface through a steam treatment
- Correction: Enhancing antibacterial property of aluminum foil by nanostructuring its surface through a steam treatment
- Enhancing antibacterial property of aluminum foil by nanostructuring its surface through a steam treatment
- Correction: Enhancing antibacterial property of aluminum foil by nanostructuring its surface through a steam treatment
- Enhancing antibacterial property of aluminum foil by nanostructuring its surface through a steam treatment
- Correction: Enhancing antibacterial property of aluminum foil by nanostructuring its surface through a steam treatment
- Enhancing antibacterial property of aluminum foil by nanostructuring its surface through a steam treatment
- Correction: Enhancing antibacterial property of aluminum foil by nanostructuring its surface through a steam treatment
- Core-Shell Electrocatalysts with Nanocolumnar Pt Thin Film Shell on Carbon Support Core for Polymer Electrolyte Membrane Fuel Cells
- Core-Shell Electrocatalysts with Nanocolumnar Pt Thin Film Shell on Carbon Support Core for Polymer Electrolyte Membrane Fuel Cells
- Core-Shell Electrocatalysts with Nanocolumnar Pt Thin Film Shell on Carbon Support Core for Polymer Electrolyte Membrane Fuel Cells
- Determination of the solid surface energy of tellurium dioxide
- Determination of the solid surface energy of tellurium dioxide
- Influence of Substrate Location and Temperature Variation on the Growth of ZnO Nanorods Synthesized by Hot Water Treatment
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