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New material to improve de-icing

The work could improve safety in aviation, energy infrastructure

Date:
November 10, 2016
Source:
University of Houston
Summary:
Icy conditions can be deadly, whether you're flying into bad weather or too close to power transmission lines during a storm. Researchers have reported the discovery of a material that can be applied to any surface to repel ice.
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Icy conditions can be deadly, whether you're flying into bad weather or too close to power transmission lines during a storm. Researchers at the University of Houston have reported the discovery of a material that can be applied to any surface to repel ice.

The material, known as a magnetic slippery surface (MAGSS) is described in the current issue of Nature Communications.

Hadi Ghasemi, Bill D. Cook Assistant Professor of mechanical engineering at UH and principal investigator for the research, said the material outperforms all others currently in use.

"Anti-icing surfaces have a critical footprint on daily lives of humans ranging from transportation systems and infrastructure to energy systems, but creation of these surfaces for low temperatures remains elusive," the researchers wrote. "Non-wetting surfaces and liquid-infused surfaces have inspired routes for the development of icephobic surfaces. However, high freezing temperature, high ice adhesion strength, and high cost have restricted their practical applications."

Ghasemi describes the material this way: One side of the surface is coated with a magnetic material, while a thin layer of magnetic fluid -- a mixture of fluid and iron oxide nanoparticles -- is deposited on the other side. The magnetic fluid faces outside. When a droplet of water hits the surface, the magnetic fluid acts as a barrier, stopping the droplet from reaching the solid surface.

"There's no adhesion of the ice to the solid surface, so it basically slides off the surface," he said.

Four of his students are listed as co-authors: Peyman Irajizad, Nazanin Farokhnia, Seyed Mohammad Sajadi and Munib Hasnain.

Potential applications range from the aircraft industry -- planes can encounter freezing rain or super-cooled water droplets while flying, leading to a buildup of ice and potentially, a crash -- to the power industry, where icing can cause power poles, towers and transmission lines to collapse.

Ultimately, Ghasemi hopes to develop the coating as a spray that can be applied to any surface. He has a patent pending on the discovery.

"These surfaces (MAGSS) provide a defect-free surface for ice nucleation and thereby lower the ice formation to close to homogenous nucleation limit," the researchers wrote. "These surfaces promise a new paradigm for development of icephobic surfaces in aviation technologies, ocean-going vessels, power transmission lines and wind turbines in extreme environments."

Among the advantages of the new material, Ghasemi said, is that it has a far lower freezing threshold than the best icephobic technology currently available -- about minus 29 degrees Fahrenheit, compared to minus 13 degrees Fahrenheit for current technology.

"These new surfaces provide the path to tackle the challenge of icing in systems, thereby improving the quality of human life," he said.


Story Source:

Materials provided by University of Houston. Note: Content may be edited for style and length.


Journal Reference:

  1. Peyman Irajizad, Munib Hasnain, Nazanin Farokhnia, Seyed Mohammad Sajadi, Hadi Ghasemi. Magnetic slippery extreme icephobic surfaces. Nature Communications, 2016; 7: 13395 DOI: 10.1038/ncomms13395

Cite This Page:

University of Houston. "New material to improve de-icing." ScienceDaily. ScienceDaily, 10 November 2016. <www.sciencedaily.com/releases/2016/11/161110130554.htm>.
University of Houston. (2016, November 10). New material to improve de-icing. ScienceDaily. Retrieved November 20, 2024 from www.sciencedaily.com/releases/2016/11/161110130554.htm
University of Houston. "New material to improve de-icing." ScienceDaily. www.sciencedaily.com/releases/2016/11/161110130554.htm (accessed November 20, 2024).

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