UK-based P2i has developed a waterproof nano-coating that protects smartphones such as the Alcatel One Touch, and Motorola's RAZR and XOOM. We think the company should develop the technology for consumers who want to apply it to the devices they already own. (Source: P2i)
I suppose there's a difference between water proof and water resistant. I know there's a difference between fire proof and fire resistant. And it has to do with self extinguishing compared to the inability to catch on fire. In both cases it's intersesting how marketing words sometimes sound similar to what we want, but in the end it's just real close.
I would define immersion as being under water for a few seconds. Dropping it in a bath tub full of water or in the toilet (as one reader described) would be an example. Can this technology withstand that? My guess would be no, because any connection to the outside world would take in water. Right?
Yes, Dave Palmer, I agree. I wasn't suggesting that this process could be marketed as "anti-cancer". I was putting the idea out there. It's a market that's waiting for the right product/attention.
The evidence isn't as weak as those in CE claim though. I'm sure it's not just cell phones placed in bras that has caused increased breast cancer in very young women. What I listended to on Pacifca radio was very compelling and gave good evidence that cell phones aren't entirely benign.
But, is there anything that's completely safe today?
Something that is molecularly bonded can't be peeled off, but ordinary wear takes the surface off anything. How many computer keys have you seen that have become smooth and shiny with age? I am sure that a plastic layer a few nanometers thick is not going to survive any process that takes micrometers off its substrate. Ordinary wear will take this stuff off in very short order. The only things that will remain protected are those that are not subject to wear.
Of course, that is much of the inside of any device.
What does this stuff do to battery contacts and pushbuttons? Is it thin enough to keep its interference to a few milliohms?
I agree with every word of what eafpres wrote. They lost me when they claimed that the coating can never wear off and that it doesn't change the electrical properties of anything. All coatings wear off unless they're extremely hard (e.g. diamaond or SiC), in which case they're hard to deposit, hard to bond, and too brittle for use on even slightly flexible substrates. As for not changing the electrical properties, that means that the coating must "know", based on where it lands, whether it ought to be an insulator or a conductor. That, of course, is impossible.
Furthermore, once moisture gets inside an electronic device, it takes a very long time to get out. That gives it plenty of time to work mischief while it's in there. To really waterproof a camera or cell phone, it's necessary to keep water from getting in. If merely coating the PCBs was sufficient, there are plenty of good conformal coatings that will do that.
My impression is that what happened here is some chemist developed a neat way to put thin hydrophobic coatings on lots of materials, and then let his marketing guy loose with the idea. The marketing guy thought to himself "what's a large market of products that are familiar to the general public that could benefit from waterproofing?", and of course his answer was "cell phones". Unfortunately he knows nothing about electronics or even about manufacturing processes.
This is a great idea - I'm surprised it hasn't come to market sooner. I, for one, could have used this a few years back, when my phone was drowned by the vigorous waves of the Atlantic ocean - blanket too close to the shoreline .... do the math. Of course, it will really be imressive when the technology is made and can be applied to your existing cell phone. Ann, any word from the company on that development?
Artificially created metamaterials are already appearing in niche applications like electronics, communications, and defense, says a new report from Lux Research. How quickly they become mainstream depends on cost-effective manufacturing methods, which will include additive manufacturing.
SpaceX has 3D printed and successfully hot-fired a SuperDraco engine chamber made of Inconel, a high-performance superalloy, using direct metal laser sintering (DMLS). The company's first 3D-printed rocket engine part, a main oxidizer valve body for the Falcon 9 rocket, launched in January and is now qualified on all Falcon 9 flights.
Lawrence Livermore National Laboratory and MIT have 3D-printed a new class of metamaterials that are both exceptionally light and have exceptional strength and stiffness. The new metamaterials maintain a nearly constant stiffness per unit of mass density, over three orders of magnitude.
Smart composites that let the material's structural health be monitored automatically and continuously are getting closer to reality. R&D partners in an EU-sponsored project have demonstrated what they say is the first complete, miniaturized, fiber-optic sensor system entirely embedded inside a fiber-reinforced composite.
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