Efficient quantum state transfer in coupled levitated nanoparticle system
POSTER
Abstract
Sandeep Sharma1, *, Seongi Hong1, and Andrey S. Moskalenko1
1Department of Physics, KAIST, Daejeon 34141, South Korea
Successful trapping and levitation of two or more nanoparticles have opened up a new avenue for exploring many-body physics such as coherent manipulation of quantum states, entanglement dynamics, tunable quantum sensing, and nonequilibrium physics using these systems [1].
We report on the creation and transfer of different quantum states in a system of two interacting levitated nanoparticles. The nanoparticles are levitated using two distinct optical tweezers and interact with each other via the scattered fields of the trapping lasers constituting the tweezers. We create a squeezed thermal state in the mechanical mode of one nanoparticle, and then by suitably changing the trapping laser phases and the inter-particle distance, we transfer it to the other nanoparticle with very high fidelity. Further, we confirm this high transfer fidelity rate by creating and transferring a coherent state as well. Our work may have potential application in quantum information processing.
[1] J. Rieser, M. A. Ciampini, H. Rudolph, N. Kiesel, K. Hornberger, B. A. Stickler, M. Aspelmeyer, and U. Delić, Science 377, 987 (2022).
1Department of Physics, KAIST, Daejeon 34141, South Korea
Successful trapping and levitation of two or more nanoparticles have opened up a new avenue for exploring many-body physics such as coherent manipulation of quantum states, entanglement dynamics, tunable quantum sensing, and nonequilibrium physics using these systems [1].
We report on the creation and transfer of different quantum states in a system of two interacting levitated nanoparticles. The nanoparticles are levitated using two distinct optical tweezers and interact with each other via the scattered fields of the trapping lasers constituting the tweezers. We create a squeezed thermal state in the mechanical mode of one nanoparticle, and then by suitably changing the trapping laser phases and the inter-particle distance, we transfer it to the other nanoparticle with very high fidelity. Further, we confirm this high transfer fidelity rate by creating and transferring a coherent state as well. Our work may have potential application in quantum information processing.
[1] J. Rieser, M. A. Ciampini, H. Rudolph, N. Kiesel, K. Hornberger, B. A. Stickler, M. Aspelmeyer, and U. Delić, Science 377, 987 (2022).
Presenters
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SANDEEP SHARMA
Korea Advanced Institute of Science and Technology
Authors
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SANDEEP SHARMA
Korea Advanced Institute of Science and Technology
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Seongi Hong
Korea Advanced Institute of Science and Technology
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Andrey S Moskalenko
Korea advanced Institute of Science and Technology