Interaction of Strain and Nuclear Spins in Silicon: Quadrupolar Effects on Ionized Donors

David P. Franke; Florian M. Hrubesch; Markus Künzl; Hans Werner Becker; Kohei M. Itoh; Martin Stutzmann; Felix Hoehne; Lukas Dreher; Martin S. Brandt

doi:10.1103/PhysRevLett.115.057601

Interaction of Strain and Nuclear Spins in Silicon: Quadrupolar Effects on Ionized Donors

David P. Franke, Florian M. Hrubesch, Markus Künzl, Hans Werner Becker, Kohei M. Itoh, Martin Stutzmann, Felix Hoehne, Lukas Dreher, Martin S. Brandt

TUM Emeriti of Excellence

Research output: Contribution to journal › Article › peer-review

30 Scopus citations

Abstract

The nuclear spins of ionized donors in silicon have become an interesting quantum resource due to their very long coherence times. Their perfect isolation, however, comes at a price, since the absence of the donor electron makes the nuclear spin difficult to control. We demonstrate that the quadrupolar interaction allows us to effectively tune the nuclear magnetic resonance of ionized arsenic donors in silicon via strain and determine the two nonzero elements of the S tensor linking strain and electric field gradients in this material to S11=1.5×1022V/m2 and S44=6×1022V/m2. We find a stronger benefit of dynamical decoupling on the coherence properties of transitions subject to first-order quadrupole shifts than on those subject to only second-order shifts and discuss applications of quadrupole physics including mechanical driving of magnetic resonance, cooling of mechanical resonators, and strain-mediated spin coupling.

Original language	English
Article number	057601
Journal	Physical Review Letters
Volume	115
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevLett.115.057601
State	Published - 29 Jul 2015

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title = "Interaction of Strain and Nuclear Spins in Silicon: Quadrupolar Effects on Ionized Donors",

abstract = "The nuclear spins of ionized donors in silicon have become an interesting quantum resource due to their very long coherence times. Their perfect isolation, however, comes at a price, since the absence of the donor electron makes the nuclear spin difficult to control. We demonstrate that the quadrupolar interaction allows us to effectively tune the nuclear magnetic resonance of ionized arsenic donors in silicon via strain and determine the two nonzero elements of the S tensor linking strain and electric field gradients in this material to S11=1.5×1022V/m2 and S44=6×1022V/m2. We find a stronger benefit of dynamical decoupling on the coherence properties of transitions subject to first-order quadrupole shifts than on those subject to only second-order shifts and discuss applications of quadrupole physics including mechanical driving of magnetic resonance, cooling of mechanical resonators, and strain-mediated spin coupling.",

author = "Franke, {David P.} and Hrubesch, {Florian M.} and Markus K{\"u}nzl and Becker, {Hans Werner} and Itoh, {Kohei M.} and Martin Stutzmann and Felix Hoehne and Lukas Dreher and Brandt, {Martin S.}",

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T1 - Interaction of Strain and Nuclear Spins in Silicon

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AU - Franke, David P.

AU - Hrubesch, Florian M.

AU - Künzl, Markus

AU - Becker, Hans Werner

AU - Itoh, Kohei M.

AU - Stutzmann, Martin

AU - Hoehne, Felix

AU - Dreher, Lukas

AU - Brandt, Martin S.

PY - 2015/7/29

Y1 - 2015/7/29

N2 - The nuclear spins of ionized donors in silicon have become an interesting quantum resource due to their very long coherence times. Their perfect isolation, however, comes at a price, since the absence of the donor electron makes the nuclear spin difficult to control. We demonstrate that the quadrupolar interaction allows us to effectively tune the nuclear magnetic resonance of ionized arsenic donors in silicon via strain and determine the two nonzero elements of the S tensor linking strain and electric field gradients in this material to S11=1.5×1022V/m2 and S44=6×1022V/m2. We find a stronger benefit of dynamical decoupling on the coherence properties of transitions subject to first-order quadrupole shifts than on those subject to only second-order shifts and discuss applications of quadrupole physics including mechanical driving of magnetic resonance, cooling of mechanical resonators, and strain-mediated spin coupling.

AB - The nuclear spins of ionized donors in silicon have become an interesting quantum resource due to their very long coherence times. Their perfect isolation, however, comes at a price, since the absence of the donor electron makes the nuclear spin difficult to control. We demonstrate that the quadrupolar interaction allows us to effectively tune the nuclear magnetic resonance of ionized arsenic donors in silicon via strain and determine the two nonzero elements of the S tensor linking strain and electric field gradients in this material to S11=1.5×1022V/m2 and S44=6×1022V/m2. We find a stronger benefit of dynamical decoupling on the coherence properties of transitions subject to first-order quadrupole shifts than on those subject to only second-order shifts and discuss applications of quadrupole physics including mechanical driving of magnetic resonance, cooling of mechanical resonators, and strain-mediated spin coupling.

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Interaction of Strain and Nuclear Spins in Silicon: Quadrupolar Effects on Ionized Donors

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