Authors: J. Vodeb, M. Diego, Y. Vaskivskyi, L. Logarić, Y. Gerasimenko, V. Kabanov, B. Lipovšek, M. Topič, and D. Mihailović
Researchers from the Department for Complex Matter at the Jožef Stefan Institute have, for the first time, used a quantum computer to model a real, non-hypothetical physical problem. Their study, “Non-equilibrium quantum domain reconfiguration dynamics in a two-dimensional electronic crystal”, represents a major milestone in quantum computation.
In their research, Jaka Vodeb, Michele Diego, Yevhenii Vaskivskyi, Leonard Logarić, Yaroslav Gerasimenko, Viktor Kabanov, Benjamin Lipovšek, Marko Topič, and Dragan Mihailović examined the quantum domain reconfiguration dynamics in an electronic superlattice of a quantum material. By combining time-resolved tunneling microscopy with superconducting quantum simulation, they were able to realistically model the dynamics of quantum systems in non-equilibrium environments. Their findings contribute significantly to understanding open quantum systems and have implications for the development of next-generation memory devices based on 1T-TaS₂.
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