Nanostructures of virtually any possible shape can now be made using a combination of techniques developed by the MESA+ Institute for Nanotechnology of the University of Twente. In particular, the unique properties of so-called perovskites have been exploited because their crystal structure is not damaged by the process. The UT scientists presented their findings in the journal Advanced Functional Materials.
Perovskites are materials with special properties, especially at their interfaces. At the interface between two non-conducting perovskites, for example, a conducting “path” can arise. The magnetic properties of perovskites are unique as well. Within the group Inorganic Materials Science, UT scientists have gained a lot of experience with these materials. Earlier, the group developed the pulsed laser deposition technique (PLD) to build the perovskite materials one atomic layer at a time. PLD has now been combined with another technique for creating patterns within these ultra thin layers. This could not be done until now, because other patterning techniques risk of damaging the crystal structure and orientation and thus influencing the properties of the material. The new combination of techniques does not show this disadvantage.
Simple mold
The solution that UT researchers published in Advanced Functional Materials combines PLD with so-called soft lithography. The mold used for creating patterns can be made relatively easy and consists of PDMS—a rubber like polymer with silicon in it. Via this mask, a pattern of zinc oxide can be placed on the perovskite, for example. Using PLD, a sandwich of different materials can be made. The properties of each layer are secured. The new structures could lead to sensors and chips for future devices like smartphones, computers and medical equipment. They are also suitable for fundamental research in physics and materials science.
Research has been done within the Inorganic Materials Science group, part of the MESA+ Institute for Nanotechnology at the University of Twente.
Patterning of epitaxial perovskites from micro and nano molded stencil masks
Source: Univ. of Twente