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Groundbreaking research by physicists at The City College of New York is being credited for a novel discovery regarding the interaction of electronic excitations via spin waves. The finding by the Laboratory for Nano and Micro Photonics (LaNMP) team headed by physicist Vinod Menon could open the door to future technologies and advanced applications such as optical modulators, all-optical logic gates, and quantum transducers. The work is reported in the journal Nature Materials.
The researchers showed the emergence of interaction between electronic excitations (excitons — electron hole pairs) mediated via spin waves in atomically thin (2D) magnets. They demonstrated that the excitons can interact indirectly through magnons (spin waves), which are like ripples or waves in the 2D material’s magnetic structure.
“Think of magnons as tiny flip-flops of atomic magnets inside the crystal. One exciton changes the local magnetism, and that change then influences another exciton nearby. It’s like two floating objects pulling toward each other by disturbing water waves around them,” said Menon. To demonstrate this, the Menon group utilized a magnetic semiconductor, CrSBr which the group had previously shown to host strong light-matter interaction (Nature, 2023).
Post-doctoral fellows Biswajit Datta and Pratap Chandra Adak led the research along with graduate students Sichao Yu and Agneya Dharmapalan in collaboration with the groups at the CUNY Advanced Science Research Center, University of Chemistry and Technology — Prague, RPTU — Kaiserslautern, Germany and NREL, USA.
“What is especially exciting about this discovery is that the interaction between excitons can be controlled externally using a magnetic field, thanks to the tunable magnetism of 2D materials. That means we can effectively switch the interaction on or off, which is hard to do with other types of interactions,” said Datta.
“One particularly exciting application enabled by this discovery is in the development of quantum transducers — devices that convert quantum signals from one frequency to another, such as from microwave to optical. These are key components for building quantum computers and enabling the quantum internet.” said Adak, another lead author of this work.
The work at CCNY was supported by U.S. Department of Energy — Office of Basic Energy Sciences, The Army Research Office, The National Science Foundation and The Gordon and Betty Moore Foundation.
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