Is it possible to have a crystal this strong? Source: Image designed by 
Now, such a material is considered the holy grail of materials, because not only would it give us a stronger screen for the cell phone, we speak that a material with these properties has the potential to make technology in optical devices and solar energy storage devices more robust and profitable.
Well, a team composed of several materials researchers from the Hamburg University of Technology and their colleagues from Berkeley University have developed a hybrid material that they call supercrystal, which is quite close to this holy grail.
Hard and yet deformable
This material is exceptional for being hard and at the same time deformable, remember that hardness and malleability are hardly properties that we can find together, for example, a glass-ceramic material is resistant to scratches and thermal expansion but it cannot be deformed, and a sheet of metal is deformable but can be easily grated using a harder material.
To make a material that combines both properties, these scientists used organically functionalized supercrystalline nanoparticles. The scientists discovered that they could arrange the particles as if they were atoms, building a three-dimensional, periodic network analogous to crystalline networks. To achieve this, they used spherical iron oxide (Fe3O4) nanoparticles, a fairly hard oxide, and an adhesion layer made of liquid oleic acid. This makes the supercrystal both hard and easy to deform. The results of the research were shown in the journal Science Advance.
The scientists demonstrated that these supercrystalline materials accommodate plastic deformation in the form of stacking, dislocation and sliding bands, which leads to even multiple strengthening of the material, giving it an elastoplastic behavior, accompanied by compaction.
The arrangement of the particles allows the plastic deformation of the material. Source:
These nanostructured supercrystalline materials are a rapidly growing field of materials science and engineering, thanks to the development of processing techniques optimized for the nanoscale. And they are finding a variety of applications in different fields, some already well established like solar panel manufacturing and optoelectronics up to their that in biomedical sensors.
The plastic deformation of metals is something that has long interested materials researchers, and the fact that this feature can be replicated in crystalline materials is a new and exciting field, one can only imagine the impact these materials will have on electronics technology, which is certainly more appealing to imagine our electronic devices with stronger and more deformable glass screens.
Thanks for coming by to read friends, I hope you liked the information. See you next time.