Laylan B. Hassan scite author profile

Surfaces with metal oxide nanostructures have gained considerable interest in applications such as sensors, detectors, energy harvesting cells, and batteries. However, conventional fabrication techniques suffer from challenges that hinder wide and effective applications of such surfaces. Most of the metal oxide nanostructure synthesis methods are costly, complicated, non-scalable, environmentally hazardous, or applicable to only certain few materials. Therefore, it is crucial to develop a simple metal oxide nanostructure fabrication method that can overcome all these limitations and pave the way to the industrial application of such surfaces. Here, we demonstrate that a wide variety of metals can form metal oxide nanostructures on their surfaces after simply interacting with hot water. This method, what we call hot water treatment, offers the ability to grow metal oxide nanostructures on most of the metals in the periodic table, their compounds, or alloys by a one-step, scalable, low-cost, and eco-friendly process. In addition, our findings reveal that a “plugging” mechanism along with surface diffusion is critical in the formation of such nanostructures. This work is believed to be of importance especially for researchers working on the growth of metal oxide nanostructures and their application in functional devices.

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Hierarchically rough superhydrophobic copper sheets fabricated by a sandblasting and hot water treatment process

Hassan

Saadi

Karabacak

2017

Int J Adv Manuf Technol

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Special wettable nanostructured copper mesh achieved by a facile hot water treatment process

Saadi

Hassan

Brozak

et al. 2017

Mater. Res. Express

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ABSTRACT:In this research, special wettable copper mesh owing superhydrophobicity and superoleophilicity property is reported using a low-cost, eco-friendly, rapid, and scalable synthesis methods. Hot water treatment (HWT) method is used to integrate the micro-textured copper mesh surface with a nanoscale roughness to achieve hierarchical micro-nano structured surface. The surface energy of the nanoscale In addition, the effect of the mesh's geometry on the wetting property was examined through correlations between wire diameter, pore size, and optimal values for the highest water CA.

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Enhancing the antibacterial efficacy of aluminum foil by nanostructuring its surface using hot water treatment^*

et al. 2021

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Bacterial biofilm has become one of the most frequent health problems as it contributes to persistent chronic infections. Therefore, it is vital to find alternatives to currently used bactericidal agents to prevent bacterial contamination on surfaces effectively and prevent the biofilms formation. Several metallic materials are well known for their antimicrobial activity; this includes copper, copper alloys, silver, gold, titanium, and zinc. On the other hand, some metals, such as aluminum, do not have noteworthy antimicrobial properties. In this study, we demonstrate that the antibacterial activity of household aluminum foil can be enhanced by nanostructuring the foil's surface by a simple hot water treatment (HWT) process. Cultures of Escherichia coli and Staphylococcus aureus were grown on nutrient agar while exposed to the samples of treated and untreated Al foils and left for 24 h. Our results indicate that treated Al foil can more effectively inhibit the bacteria growth compared to the regular untreated Al foil. This enhancement in antibacterial property might be due to a combination of chemical and morphological changes that the cell undergoes once it encounters nanofeatures of HWT-Al foil surface.

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Laylan B. Hassan

Metal oxide nanostructures by a simple hot water treatment

Hierarchically rough superhydrophobic copper sheets fabricated by a sandblasting and hot water treatment process

Special wettable nanostructured copper mesh achieved by a facile hot water treatment process

Enhancing the antibacterial efficacy of aluminum foil by nanostructuring its surface using hot water treatment^*

Contact Info

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About

Laylan B. Hassan

Metal oxide nanostructures by a simple hot water treatment

Hierarchically rough superhydrophobic copper sheets fabricated by a sandblasting and hot water treatment process

Special wettable nanostructured copper mesh achieved by a facile hot water treatment process

Enhancing the antibacterial efficacy of aluminum foil by nanostructuring its surface using hot water treatment *

Contact Info

Product

Resources

About

Enhancing the antibacterial efficacy of aluminum foil by nanostructuring its surface using hot water treatment^*