Trions exhibit novel characteristics in moiré superlattices eurekalert.org - get the latest breaking news, showbiz & celebrity photos, sport news & rumours, viral videos and top stories from eurekalert.org Daily Mail and Mail on Sunday newspapers.
When two similar atomic layers with mismatching lattice constants the constant distance between a layer’s unit cells and/or orientation are stacked together, the resulting bilayer can exhibit a moiré pattern and form a moiré superlattice.
Twisting Atomically Thin Semiconductor Materials may Convert Light into Electricity
Written by AZoOpticsMay 3 2021
A pair of physicists at the University of California, Riverside, are aiming to convert light falling on atomically thin semiconductor materials into electricity, having received more than $582,000 in funding from the U.S. Department of the Army.
Nathaniel Gabor and Vivek Aji, both associate professors of physics and astronomy, will focus on how the fundamental science of light and its interaction with matter enables new sensing capabilities in layered and twisted vertical structures of stacked monolayer semiconductors. The researchers aim to understand how electronic excitations influence the flow of photo-absorbed energy in ultrasmall semiconducting optoelectronic materials.
E-Mail
IMAGE: Photo shows Vivek Aji (left) and Nathaniel Gabor in the Quantum Materials Optoelectronics Lab at UC Riverside. view more
Credit: Stan Lim, UC Riverside.
RIVERSIDE, Calif. A pair of physicists at the University of California, Riverside, are aiming to convert light falling on atomically thin semiconductor materials into electricity, having received more than $582,000 in funding from the U.S. Department of the Army.
Nathaniel Gabor and Vivek Aji, both associate professors of physics and astronomy, will focus on how the fundamental science of light and its interaction with matter enables new sensing capabilities in layered and twisted vertical structures of stacked monolayer semiconductors. The researchers aim to understand how electronic excitations influence the flow of photo-absorbed energy in ultrasmall semiconducting optoelectronic materials.