(Funded by the U.S. Department of Energy)
Researchers from Penn State; Columbia University; the National Renewable Energy Laboratory in Golden, CO; TUD Dresden University of Technology in Germany; Kingβs College London; Radboud University in the Netherlands; the University of Chemistry and Technology Prague in the Czech Republic; and the University of Regensburg in Germany have identified a surface exciton β an excited electron and the hole it leaves behind β in chromium sulfide bromide, a layered magnetic semiconductor. Cooling chromium sulfide bromide down to around β223 degrees Fahrenheit brings it to a ground state, or the state of lowest energy. This transforms it into an antiferromagnetic system, in which the magnetic moments β referred to as βspinβ β of the systemβs particles align in a regular, repeating pattern. This antiferromagnetic ordering ensures that each layer alternates its magnetic alignment. As a result, excitons tend to stay in the layer with the same spin. Like cars on alternating one-way streets, these established boundaries keep excitons confined to the layer with which they share the same spin directions.
Categories: NNI-NEWS, U.S. Department of Energy
