Shape-memory polymer (Motorola patents a self-healing phone screen)

Motorola patents a self-healing phone screen
Expensive repairs could be a thing of the past, thanks to Motorola’s “shape memory polymer”

It’s hard not to wince when you drop your phone on the floor. Tentatively pick it up to inspect the damage and, if you’re unlucky, you’ll be left with a spiderweb of cracks spread across your touchscreen. Normally that means a trip to the phone repair shop, but Motorola is working on a solution that could let your handset repair itself.
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Properties of shape-memory polymers
SMPs can retain two or sometimes three shapes, and the transition between those is induced by temperature. In addition to temperature change, the shape change of SMPs can also be triggered by an electric or magnetic field,[2] light[3]or solution.[4] As well as polymers in general, SMPs also cover a wide property-range from stable to biodegradable, from soft to hard, and from elastic to rigid, depending on the structural units that constitute the SMP. SMPs include thermoplastic and thermoset (covalently cross-linked) polymeric materials. SMPs are known to be able to store up to three different shapes in memory.[5] SMPs have demonstrated recoverable strains of above 800%.[6]

Two important quantities that are used to describe shape-memory effects are the strain recovery rate (Rr) and strain fixity rate (Rf). The strain recovery rate describes the ability of the material to memorize its permanent shape, while the strain fixity rate describes the ability of switching segments to fix the mechanical deformation.


Result of the cyclic thermomechanical test
{\displaystyle R_{r}(N)={\frac {\varepsilon _{m}-\varepsilon _{p}(N)}{\varepsilon _{m}-\varepsilon _{p}(N-1)}}}
{\displaystyle R_{f}(N)={\frac {\varepsilon _{p}(N)}{\varepsilon _{m}}}}
where N is the cycle number, ?m is the maximum strain imposed on the material, and ?p(N) and ?p(N-1) are the strains of the sample in two successive cycles in the stress-free state before yield stress is applied.

Shape-memory effect can be described briefly as the following mathematical model:[7]

{\displaystyle R_{f}(N)=1-{\frac {E_{f}}{E_{g}}}}
{\displaystyle R_{r}(N)=1-{\frac {f_{IR}}{f_{\alpha }(1-E_{f}/E_{g})}}}
where Eg is the glassy modulus, Er is the rubbery modulus, fIR is viscous flow strain and f? is strain for t >> tr.

Triple-shape memory[edit]
While most traditional shape-memory polymers can only hold a permanent and temporary shape, recent technological advances have allowed the introduction of triple-shape-memory materials. Much as a traditional double-shape-memory polymer will change from a temporary shape back to a permanent shape at a particular temperature, triple-shape-memory polymers will switch from one temporary shape to another at the first transition temperature, and then back to the permanent shape at another, higher activation temperature. This is usually achieved by combining two double-shape-memory polymers with different glass transition temperatures[8] or when heating a programmed shape-memory polymer first above the glass transition temperature and then above the melting transition temperature of the switching segment.[9][10]
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(EBOOK)
Investigation into the use of engineering polymers as acutators to produce 'automatic disassembly'of electronic products

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Well i hope it`s better than the before and after photo i saw a few weeks ago (maybe a different process), the crack could still be seen, I hope they perfect it though.



John.