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Building functional nanostructures for clean energy technology through organic chemistry.

Next-2Digits develops integration technologies for 2D materials in photonic and optoelectronic circuits. The project enhances performance and cost-efficiency in optical sensors while boosting European innovation through scalable manufacturing.

Advanced Functional Materials, AFM, is an interdisciplinary research environment conducting studies in advanced functional materials. The initiative is based on a government investment with strategic research areas as its foundation.

Our vision is to create the next generation of green, cheap, reliable energy devices for the coming revolution of internet of everything. The emphasis is to combine energy conversion and mechanical compatibility for flexible and wearable electronics.

We work on development and characterization of chemical gas sensors, silicon carbide field effect transistors, graphene and other 2D materials for gas sensors.

By introducing defects into the perfect surface of graphene on silicon carbide, researchers at LiU have increased the capacity of the material to store electrical charge. The finding stimulates ideas on how this ultrathin material might be used.

Low-frequency light reveals internal structures and properties in all conceivable materials. A research team at LiU has built a one-of-a-kind spectrometer that analyses samples with electromagnetic waves in the terahertz range.

Professor Johanna Rosén, together with colleagues, has been awarded SEK 29 million from the Knut and Alice Wallenberg Foundation. AI is to be added to the tools used to seek two-dimensional materials with completely new properties.

Researchers at LiU are working to develop a method to convert water and carbon dioxide to the renewable energy of the future, using the energy from the sun and graphene applied to the surface of cubic silicon carbide.

Researchers at LiU are attempting to convert carbon dioxide, a greenhouse gas, to fuel using energy from sunlight. Recent results have shown that it is possible to use their technique to selectively produce methane, carbon monoxide or formic acid.