Professor makes the case for Supercool Metals (w/ Video)

Professor makes the case for Supercool Metals
According to Yale researcher Jan Schroers, This material is 50 times harder than plastic, nearly 10 times harder than aluminum and almost three times the hardness of steel."

Someday, digital citizens around the world may have a Yale professor to thank for the supercool, extra-durable case protecting their smartphones.

Jan Schroers, who teaches mechanical engineering and materials science, has created a thin, lightweight smartphone case that is harder than steel and as easy to shape as plastic. Schroers developed the technology for the cases in his Yale lab; now he's ready for a partner to bring the product into mass production.

"This material is 50 times harder than plastic, nearly 10 times harder than aluminum and almost three times the hardness of steel," Schroers said. "It's awesome."

For years, academic and commercial institutions have sought an effective technique for shaping these bulk metallic glasses (BMGs)—a new generation of strong-yet-pliable materials. Electronics casings, in particular, have been identified as a desirable application. Yet past attempts at finding a shaping process were unsuccessful.

At Yale, Schroers spent much of the past decade pursuing a fundamentally different approach to precisely shaping complex geometries. Instead of melting the BMG material and forcing it into a mold at high temperatures, he utilized a unique, supercooled liquid state for the material, in which the BMG softens sufficiently to allow for shaping. With this technique, which Schroers calls thermoplastic forming, BMGs can be shaped like plastics. As a consequence, thermoplastic forming BMGs don't require massive amounts of energy.

From there, Schroers focused on producing BMGs in sheets. That form, he reasoned, is the most conducive to practical, manufacturing applications. "Developing a fabrication method for BMG sheets has been extremely difficult because it requires a fundamentally different process," Schroers said. "We succeeded recently, with a surprisingly versatile process that is fast, precise, and economical."

Schroers' method produces sheets that can be used in standard manufacturing operations and blow-molded into an array of shapes. Schroers' lab also created a BMG blow-molding process, which can be carried out as easily as the process for blow-molding plastics.

Seeing the commercial potential for his technique, Schroers launched his own company, Supercool Metals. The company has exclusive licensing rights to the technology, which is owned by Yale. "We're taking a great scientific idea and making it viable in the larger world," said Tobias Noesekabel, Supercool Metals' intern and an M.B.A. candidate at the Yale School of Management.

Until now, Schroers has focused on smaller-scale, specialty production items, including watch components and sensors. Smartphone cases were a natural, but challenging, next step.

"It's obvious. The important properties in a cell phone case are hardness and weight," Schroers explained.

He and his Yale team—postgraduate associate Rodrigo Miguel Ojeda Mota and graduate students Jittisa Ketkaew and Wen Chen—produce the cases by blow-molding BMG sheets into brass molds to precise specifications. Of particular note is the ability to design metal buttons into the sides of the case, which constitutes a huge advance in making smartphones more waterproof.

With the right manufacturing partner, Schroers said, he could scale up production by late 2015. He added that design work and production could remain local.

"We see ourselves doing this close to Yale," Schroers said.


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Citation: Professor makes the case for Supercool Metals (w/ Video) (2014, September 8) retrieved 19 October 2019 from https://phys.org/news/2014-09-professor-case-supercool-metals-video.html
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Sep 08, 2014
So, why not just build the phones from this material, instead of a bulky case?

Sep 08, 2014
All of the other materials in the phone require vastly different properties.

Sep 08, 2014
Parts for phones must be comprised of conductors, insulators, semiconductors, and other materials for other requirements, such as transparency and photon emission.. The chips are of pure Silicon, "doped" with charge carriers, photolithographed, with masks stacked. Their conductors are vapor-deposited. They are bonded to the leadframes with tiny Silver wires, and most packages molded on. They are tested electronically on wafers and in final test. Circuit boards containing the active devices are multilayer, with conductors plated through appropriate layers. They are fitted with cases of injection-molded (at several thousand PSI), high-impact plastics, formed metal, or other materials.

Sep 08, 2014
This comment has been removed by a moderator.

Sep 08, 2014
nice article :) for more tech tricks and latest gadget news and reviews visit >>>>>www.techdial.in

Sep 08, 2014
An unbreakable phone case would definitely reduce sales volume.
Why would anyone want that?

Sep 09, 2014
Unbreakable but un-last-years-model?

Sep 09, 2014
He says zirconium and copper, and perhaps other combinations. Nothing about corrosion. I wonder if you could make a DeLorean out of it? Flexibility would work well with bumpers.

NOM
Sep 11, 2014
An unbreakable phone case would definitely reduce sales volume.
Why would anyone want that?

That's why it's just the case. When the inside is no longer cool enough, swap it out.

Sep 14, 2014
to be removed please

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