Laylan B. Hassan Data-verified
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Biography and Research Information
OverviewAI-generated summary
Laylan B. Hassan's research focuses on the fabrication and characterization of nanostructured surfaces with specific functional properties. Recent publications investigate methods for enhancing antibacterial efficacy through surface nanostructuring, the creation of superhydrophobic metal surfaces using sandblasting and hot water treatments, and the growth of zinc oxide nanowires via a hot water deposition method. Hassan's work also explores the development of durable superhydrophobic-superoleophilic nanostructured surfaces for oil-water separation and the fabrication of robust superamphiphobic surfaces through dual sandblasting and steam treatment. Additionally, research includes studying the photocurrent response of core-shell nanostructures fabricated by hot water treatment. Hassan has a h-index of 5, with 10 total publications and 195 total citations. Key collaborators include Tansel Karabacak and Nawzat S. Saadi from the University of Arkansas at Little Rock.
Metrics
- h-index: 5
- Publications: 10
- Citations: 198
Selected Publications
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Fabrication of robust and durable superamphiphobic aluminum alloy and zinc surfaces via dual sandblasting and steam treatment (2025)
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Scalable and durable superhydrophobic-superoleophilic nanostructured zinc-coated steel wool for efficient oil-water separation (2025)
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Enhanced dropwise condensation using superhydrophobic surfaces with hierarchical roughness: A scalable and eco-friendly approach (2025)
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Hierarchically rough superhydrophobic metal surfaces fabricated by a sandblasting and hot water treatment process (2025)
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Growth of zinc oxide nanowires by a hot water deposition method (2024)
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Enhancing the antibacterial efficacy of aluminum foil by nanostructuring its surface using hot water treatment <sup>*</sup> (2021)
Collaboration Network
Top Collaborators
- Enhancing the antibacterial efficacy of aluminum foil by nanostructuring its surface using hot water treatment <sup>*</sup>
- Hierarchically rough superhydrophobic metal surfaces fabricated by a sandblasting and hot water treatment process
- Growth of zinc oxide nanowires by a hot water deposition method
- Enhanced dropwise condensation using superhydrophobic surfaces with hierarchical roughness: A scalable and eco-friendly approach
- Scalable and durable superhydrophobic-superoleophilic nanostructured zinc-coated steel wool for efficient oil-water separation
Showing 5 of 7 shared publications
- Enhancing the antibacterial efficacy of aluminum foil by nanostructuring its surface using hot water treatment <sup>*</sup>
- Hierarchically rough superhydrophobic metal surfaces fabricated by a sandblasting and hot water treatment process
- Growth of zinc oxide nanowires by a hot water deposition method
- Enhanced dropwise condensation using superhydrophobic surfaces with hierarchical roughness: A scalable and eco-friendly approach
- Scalable and durable superhydrophobic-superoleophilic nanostructured zinc-coated steel wool for efficient oil-water separation
Showing 5 of 6 shared publications
- Enhancing the antibacterial efficacy of aluminum foil by nanostructuring its surface using hot water treatment <sup>*</sup>
- Enhancing the antibacterial efficacy of aluminum foil by nanostructuring its surface using hot water treatment <sup>*</sup>
- Enhancing the antibacterial efficacy of aluminum foil by nanostructuring its surface using hot water treatment <sup>*</sup>
- Enhancing the antibacterial efficacy of aluminum foil by nanostructuring its surface using hot water treatment <sup>*</sup>
- Photocurrent Response of Cuo-Shell/Zno-Core Nanostructures Fabricated by a Hot Water Treatment Method
- Growth of zinc oxide nanowires by a hot water deposition method
- Growth of zinc oxide nanowires by a hot water deposition method
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