This article is from the source 'bbc' and was first published or seen on . It last changed over 40 days ago and won't be checked again for changes.
You can find the current article at its original source at http://www.bbc.co.uk/news/science-environment-30915266
The article has changed 3 times. There is an RSS feed of changes available.
| Version 0 | Version 1 |
|---|---|
| Laser-etched metal 'bounces' water | Laser-etched metal 'bounces' water |
| (about 2 hours later) | |
| Physicists in the US have created metal surfaces that repel water to the extent that droplets bounce away. | Physicists in the US have created metal surfaces that repel water to the extent that droplets bounce away. |
| They sculpted the surface of small pieces of platinum, titanium and brass using a very high-powered laser. | They sculpted the surface of small pieces of platinum, titanium and brass using a very high-powered laser. |
| The materials "self-clean" because water droplets gather dust particles before they slide away. | The materials "self-clean" because water droplets gather dust particles before they slide away. |
| If it can be scaled up, the technique could help produce hygienic, easily-maintained devices - from solar panels to toilets - that do no rust or ice up. | If it can be scaled up, the technique could help produce hygienic, easily-maintained devices - from solar panels to toilets - that do no rust or ice up. |
| The team, from the University of Rochester in New York, reported their findings in the Journal of Applied Physics. | The team, from the University of Rochester in New York, reported their findings in the Journal of Applied Physics. |
| Many efforts to produce such "superhydrophobic" surfaces have relied on coatings, but this approach permanently changes the shape of the metal's surface. | |
| "The structures created by our laser on the metals are intrinsically part of the material surface," said senior author Prof Chunlei Guo. | "The structures created by our laser on the metals are intrinsically part of the material surface," said senior author Prof Chunlei Guo. |
| "The material is so strongly water-repellent, the water actually gets bounced off. Then it lands on the surface again, gets bounced off again, and then it will just roll off from the surface." | "The material is so strongly water-repellent, the water actually gets bounced off. Then it lands on the surface again, gets bounced off again, and then it will just roll off from the surface." |
| Prof Guo's team etched parallel grooves into the metals, 0.1mm apart, using rapid pulses of a laser beam that are extremely strong but extremely brief - lasting just a few quadrillionths of a second. | Prof Guo's team etched parallel grooves into the metals, 0.1mm apart, using rapid pulses of a laser beam that are extremely strong but extremely brief - lasting just a few quadrillionths of a second. |
| On close inspection, these grooves are covered in complex "nanostructures" that give the surface its remarkable properties. | On close inspection, these grooves are covered in complex "nanostructures" that give the surface its remarkable properties. |
| Immediately following the treatment, water actually sticks very easily to the metal surface. But as soon as it comes into contact with air, it becomes almost impossible to get wet. | Immediately following the treatment, water actually sticks very easily to the metal surface. But as soon as it comes into contact with air, it becomes almost impossible to get wet. |
| Slippery slope | |
| Water droplets released from 2cm above the surface bounce back to a height of 5mm, maintaining 30% of their energy. And any drops sitting on the surface, given half a chance, will slide away. | Water droplets released from 2cm above the surface bounce back to a height of 5mm, maintaining 30% of their energy. And any drops sitting on the surface, given half a chance, will slide away. |
| These materials are even slipperier than Teflon, a hydrophobic material well-known from non-stick frying pans. | These materials are even slipperier than Teflon, a hydrophobic material well-known from non-stick frying pans. |
| To make water droplets slide off a Teflon surface, it must be tilted to nearly 70 degrees; these new laser-etched materials will shed droplets at an angle of just four degrees. | To make water droplets slide off a Teflon surface, it must be tilted to nearly 70 degrees; these new laser-etched materials will shed droplets at an angle of just four degrees. |
| The researchers also covered some samples in dust from a vacuum cleaner. Three water droplets cleaned half the dust particles away, while 10-15 left the metal surface completely clean and dry. | The researchers also covered some samples in dust from a vacuum cleaner. Three water droplets cleaned half the dust particles away, while 10-15 left the metal surface completely clean and dry. |
| Prof Guo hopes that his research will help make better devices for collecting rain water, or easily-cleaned, hygienic surfaces for medical or sanitary purposes, particularly in developing countries. | Prof Guo hopes that his research will help make better devices for collecting rain water, or easily-cleaned, hygienic surfaces for medical or sanitary purposes, particularly in developing countries. |
| For these hopes to come to fruition, the technique needs to get faster and cheaper; currently patterning a one-inch square of metal takes one hour. | For these hopes to come to fruition, the technique needs to get faster and cheaper; currently patterning a one-inch square of metal takes one hour. |
| Prof Philip Moriarty from the University of Nottingham, a member of the Institute of Physics' Nanoscale Physics and Technology Group, said the work was "intriguing" but would not change the world overnight. | |
| "I don't think it's going to be done on an industrial scale any time soon," he told the BBC. | |
| "There are many ways of creating superhydrophobic surfaces," he added, including chemical etching and the use of electron beams, which might be more straightforward. | |
| "Femtosecond laser pulses are always interesting because you dump so much power into the surface that you really do a lot of damage. That's what they're doing - they're creating lots and lots of microstructures and nanostructures on the surface." | |
| Several years ago, work in Prof Guo's laboratory already showed that this sort of laser treatment could blacken a variety of metals - including platinum and gold. | |
| "By roughening up the surface, you change the optical properties dramatically," Prof Moriarty explained. | |
| "The advance of this work seems to be that they've taken the same technique... and looked at the surface energy properties. | |
| "The most interesting aspect is that you're modifying the optical properties and the wetting properties in concert." | |
| Follow Jonathan on Twitter |