TY - JOUR
T1 - Atomic clock transitions in silicon-based spin qubits
AU - Wolfowicz, Gary
AU - Tyryshkin, Alexei M.
AU - George, Richard E.
AU - Riemann, Helge
AU - Abrosimov, Nikolai V.
AU - Becker, Peter
AU - Pohl, Hans Joachim
AU - Thewalt, Mike L.W.
AU - Lyon, Stephen A.
AU - Morton, John J.L.
N1 - Funding Information:
The authors thank S. Simmons, T. Monteiro and S. Balian for discussions. This research is supported by the Engineering and Physical Sciences Research Council through the Materials World Network (EP/I035536/1) and a Doctoral Training Award, as well as by the European Research Council under the European Community’s Seventh Framework Programme (FP7/2007–2013)/ERC (grant agreement no. 279781). Work at Princeton was supported by the National Science Foundation through Materials World Network (DMR-1107606) and through the Princeton Materials Research Science and Engineering Center (DMR-0819860) and the National Security Agency/Laboratory for Physical Sciences through Lawrence Berkley National Laboratory (6970579). J.J.L.M. is supported by the Royal Society.
PY - 2013/8
Y1 - 2013/8
N2 - A major challenge in using spins in the solid state for quantum technologies is protecting them from sources of decoherence. This is particularly important in nanodevices where the proximity of material interfaces, and their associated defects, can play a limiting role. Spin decoherence can be addressed to varying degrees by improving material purity or isotopic composition, for example, or active error correction methods such as dynamic decoupling (or even combinations of the two). However, a powerful method applied to trapped ions in the context of atomic clocks is the use of particular spin transitions that are inherently robust to external perturbations. Here, we show that such 'clock transitions' can be observed for electron spins in the solid state, in particular using bismuth donors in silicon. This leads to dramatic enhancements in the electron spin coherence time, exceeding seconds. We find that electron spin qubits based on clock transitions become less sensitive to the local magnetic environment, including the presence of 29 Si nuclear spins as found in natural silicon. We expect the use of such clock transitions will be of additional significance for donor spins in nanodevices, mitigating the effects of magnetic or electric field noise arising from nearby interfaces and gates.
AB - A major challenge in using spins in the solid state for quantum technologies is protecting them from sources of decoherence. This is particularly important in nanodevices where the proximity of material interfaces, and their associated defects, can play a limiting role. Spin decoherence can be addressed to varying degrees by improving material purity or isotopic composition, for example, or active error correction methods such as dynamic decoupling (or even combinations of the two). However, a powerful method applied to trapped ions in the context of atomic clocks is the use of particular spin transitions that are inherently robust to external perturbations. Here, we show that such 'clock transitions' can be observed for electron spins in the solid state, in particular using bismuth donors in silicon. This leads to dramatic enhancements in the electron spin coherence time, exceeding seconds. We find that electron spin qubits based on clock transitions become less sensitive to the local magnetic environment, including the presence of 29 Si nuclear spins as found in natural silicon. We expect the use of such clock transitions will be of additional significance for donor spins in nanodevices, mitigating the effects of magnetic or electric field noise arising from nearby interfaces and gates.
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U2 - 10.1038/nnano.2013.117
DO - 10.1038/nnano.2013.117
M3 - Article
C2 - 23793304
AN - SCOPUS:84881373783
SN - 1748-3387
VL - 8
SP - 561
EP - 564
JO - Nature Nanotechnology
JF - Nature Nanotechnology
IS - 8
ER -