Optical pumping and readout of bismuth hyperfine states in silicon for atomic clock applications

Optical pumping and readout of bismuth hyperfine states in silicon for atomic clock applications

The push for a semiconductor-based quantum information technology has renewed interest in the spin states and optical transitions of shallow donors in silicon, including the donor bound exciton transitions in the near-infrared and the Rydberg, or hydrogenic, transitions in the mid-infrared. The deep...

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Bibliographic Details
Published in:Scientific reports Vol. 5; no. 1; p. 10493
Main Authors: Saeedi, K., Szech, M., Dluhy, P., Salvail, J.Z., Morse, K.J., Riemann, H., Abrosimov, N.V., Nötzel, N., Litvinenko, K.L., Murdin, B.N., Thewalt, M.L.W.
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 20-05-2015
Nature Publishing Group
Subjects:
140/125
639/301/119/1000
639/624/399/1099
Bismuth
Helium
Humanities and Social Sciences
I.R. radiation
Information technology
multidisciplinary
Rubidium
Science
Silicon
Splitting
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Summary:The push for a semiconductor-based quantum information technology has renewed interest in the spin states and optical transitions of shallow donors in silicon, including the donor bound exciton transitions in the near-infrared and the Rydberg, or hydrogenic, transitions in the mid-infrared. The deepest group V donor in silicon, bismuth, has a large zero-field ground state hyperfine splitting, comparable to that of rubidium, upon which the now-ubiquitous rubidium atomic clock time standard is based. Here we show that the ground state hyperfine populations of bismuth can be read out using the mid-infrared Rydberg transitions, analogous to the optical readout of the rubidium ground state populations upon which rubidium clock technology is based. We further use these transitions to demonstrate strong population pumping by resonant excitation of the bound exciton transitions, suggesting several possible approaches to a solid-state atomic clock using bismuth in silicon, or eventually in enriched 28 Si.
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ISSN:2045-2322
2045-2322
DOI:10.1038/srep10493