2D 'lego' Shows New Method For Creating Electronics
Scientists show how new hybrid material can be precisely controlled by twisting stacked atomic layers
Physicists from the University of Manchester and the University of Sheffield have discovered that when two atomically thin (2D) materials like graphene are placed on top of each other like a ‘Lego' tower, their properties change and a material with novel hybrid properties emerges, paving the way for design of new materials and nano devices.
This happens without the two atomic layers physically meeting, nor through a chemical reaction, but by attaching the layers to each other via van der Waals interaction - similar to how a sticky tape attaches to a flat surface.
In the ground-breaking study 'Resonantly hybridised excitons in moire superlattices in van der Waals heterostructures' published in Nature, the team also found that the properties of the new hybrid material can be precisely controlled by twisting the two stacked atomic layers, opening the way for the unique design of new materials and electronic devices for future technologies. The work also involved scientists from Ulsan National Institute of Science and Technology (Republic of Korea), National Institute for Materials Science (Japan) and the University of Oxford.
The idea of stacking layers of different materials to make so-called heterostructures goes back to the 1960s, when GaAs was first researched for making miniature lasers. Today, heterostructures are common and are used very broadly in semiconductor industry as a tool to design and control electronic and optical properties in devices.
More recently in the era of atomically thin 2D crystals, such as graphene, new types of heterostructures have emerged, where atomically thin layers are held together by relatively weak van der Waals forces.
These ‘van der Waals heterostructures' open a huge potential to create numerous designer-materials and novel devices by stacking together any number of atomically thin layers. Hundreds of combinations become possible otherwise inaccessible in traditional 3Dl materials, potentially giving access to new unexplored optoelectronic device functionality or unusual material properties.
In the study the researchers used van der Waals heterostructures made out of transition metal dichalcogenides (TMDs) in this case MoSe2 and WS2.They found that when two atomically thin semiconducting TMDs are combined in a single structure their properties hybridise, and this hybridisation makes electrons in the hetorostructure feel the effect of moiré periodic structure that always appears when to lattices with slightly different period or with the same period but a small twist angle are placed on the top of each other.
Tartakovskii added: “The more complex picture of interaction between atomically thin materials within van der Waals heterostructures emerges. This is exciting, as it gives the opportunity to access an even broader range of material properties such as unusual and twist-tunable electrical conductivity and optical response, magnetism etc. This could and will be employed as new degrees of freedom when designing new 2D-based devices.”
Scientists believe the study shows huge potential for the creation of new types of materials and devices.
Vladimir Falko, Director of the National Graphene Institute said: “By controlling the hybridisation of electron's states in heterostructures and also using moiré superlattice effedts, which are generic for heterostructures of atomically thing films, we acquire a new handle for tailoring optical properties of materials.”
Researchers would like to do further studies to explore more material combinations to discover the capabilities of the new method.