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New Study Shows Water-repellent Coatings Enable Easy Ice Removal

Published on 2017-10-23. Author : SpecialChem

Water-repellent surfaces and coatings could make ice removal a literal breeze by forcing ice to grow up rather than just skate by, says a new study from the University of Nebraska-Lincoln and several Chinese institutions.

Antiice Coatings
New Study Shows Water-repellent Coatings Enable Easy Ice Removal

Water-repellent Coatings

The research findings suggest that applying water-repellent coatings to windshields before winter storms – or engineering surfaces that inherently repel water – could enable a strong breeze to handle the burden of ice removal.

Experiments and simulations showed that a water droplet on a repellent surface will freeze upward into a microscopic six-armed formation that resembles an idealized snowflake, with only a small portion of its base adhering to the surface. This makes sense given that water droplets bead up rather than spread out over repellent surfaces, said Nebraska co-author Xiao Cheng Zeng.

Onward or Upward

Temperature and pressure mostly dictate how water droplets crystallize in open air, and those variables do factor into ice formation on solid surfaces, Zeng said. But the team’s study suggests that a surface’s contact angle – the angle formed where a water droplet meets a solid surface – determines whether ice will grow along or off the surface.

Whereas a hydrophilic surface allows water to spread across it at a small contact angle, a water-repelling hydrophobic surface will force droplets to bead up and form a larger angle.

Whether water freezes in one way or the other is up to the surface, not the temperature,” Zeng said. “It’s almost entirely dependent on the contact angle.

On a defect-free surface fabricated in the lab or modeled in a computer simulation, ice transitions from along-surface to off-surface growth at a contact angle of somewhere between 30 and 40 degrees, the team found.

The researchers also discovered that increasing the roughness of a surface by enlarging its nanoscopic pores actually decreased this angular threshold, meaning that rougher surfaces need not be as water-repellent to foster the growth of more-easily removed ice.

Breaking The Ice

  • To compare the two forms of ice growth, the researchers designed a transparent surface split into halves: one hydrophilic, one hydrophobic.
  • They then attached a high-speed camera to a microscope, capturing video of the respective processes both from beneath and from a side profile
  • When the researchers subjected both halves to puffs of air, they found that ice abandoned the hydrophobic half but steadfastly held to the hydrophilic side
  • Ice that advanced across the hydrophilic half abruptly halted when it neared hydrophobic territory

People have been studying how water interacts with surfaces for a long, long time,” Zeng said. “But this phenomenon was off the radar until now.” 

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Source: University of Nebraska-Lincoln
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