Toward Quantum Computing Experiments Using Trapped Electrons
POSTER
Abstract
Trapped electrons are promising candidates for quantum computation combining the high-performance of trapped ions and the high speed of superconducting qubit experiments in a single and scalable platform. The quantum information can be encoded in the electron’s spin state, which allows for using well-known microwave technology to read out and manipulate the qubit, while avoiding complex laser systems. Here we present our progress toward trapping and manipulating electrons in a microsized 3D-printed linear Paul trap, which will be fabricated using two-photon direct laser writing polymerization technology. In the future, we plan to implement a non-destructive quantum state readout of electrons at cryogenic temperatures in such traps.
Presenters
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Kayla J Rodriguez
University of California, Riverside
Authors
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Kayla J Rodriguez
University of California, Riverside
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Authur Suits
Princeton University, Aalto University, U.S. Naval Research Laboratory, Louisiana State University, University of South Florida, DBIO, Boston College, QCD Labs, Aalto University, DMP, Univeristy of Chicago, University of California, Berkeley, University of Delaware, University of Missouri
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Alberto M Alonso
University of California, Berkeley
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Jackie Caminiti
University of California, Berkeley
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Kristin M Beck
Lawrence Livermore National Laboratory, Lawerence Livermore National Laboratory
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Dietrich Leibfried
National Institute of Standards and Technology
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Madhav Dhital
University of California, Riverside
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Hartmut Haeffner
University of California, Berkeley
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Boerge Hemmerling
UC Riverside, University of California, Riverside