Donny R. Pearson Jr.,1 Zachary W. Riedel,1 Manohar H. Karigerasi,1 Julio Soareshttps://orcid.org/0000-0001-8617-4658,1 Elizabeth A. Goldschmidt,1 Daniel P. Shoemaker1
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Rare-earth ions in solids at cryogenic temperatures are a promising candidate for quantum memory devices due to their long-lived coherence properties. In currently available europium-doped materials, site-to-site variations of the energy levels cause inhomogeneous broadening that prevents resolution of long-lived spin states. These spin states can be resolved with spectral hole burning techniques at the expense of limiting the memory bandwidth and efficiency and by lowering the optical depth. A stoichiometric material has previously demonstrated sufficiently narrow linewidths without sacrificing optical depth. Here we present progress on europium stoichiometric materials as candidates for quantum memory applications.
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Donny R. Pearson Jr., Zachary W. Riedel, Manohar H. Karigerasi, Julio Soares, Elizabeth A. Goldschmidt, Daniel P. Shoemaker, "Stoichiometric rare-earth materials as a platform for quantum memory devices," Proc. SPIE PC12446, Quantum Computing, Communication, and Simulation III, PC1244607 (9 March 2023); https://doi.org/10.1117/12.2656078