Coherence time of decoupled nuclear spins in silicon

Ladd, Thaddeus D.; Maryenko, D.; Yamamoto, Yoshihisa; Abe, Eiichi; Itoh, Kohei M.

doi:10.1103/physrevb.71.014401

Cited by 153 publications

(153 citation statements)

References 54 publications

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“…19,20 Controlling this source of decoherence is of major interest and an active field of research. 18,[21][22][23][24][25][26] Alternatives to III-V semiconductors with inherent nuclear spins are systems composed of atoms without nuclear magnetic moments, such as Si and C. [27][28][29] Natural silicon consists of three isotopes: 28 Si (92.2%), 29 Si (4.7%), and 30 Si (3.1%). 30 Hereof only 29 Si has nonzero nuclear spin (I = 1/2), and purification can further reduce its abundance down to 0.05%.…”

Section: Introductionmentioning

confidence: 99%

Theory of spin relaxation in two-electron laterally coupled Si/SiGe quantum dots

2012

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Highly accurate numerical results of phonon-induced two-electron spin relaxation in silicon double quantum dots are presented. The relaxation, enabled by spin-orbit coupling and the nuclei of 29 Si (natural or purified abundance), is investigated for experimentally relevant parameters, the interdot coupling, the magnetic field magnitude and orientation, and the detuning. We calculate relaxation rates for zero and finite temperatures (100 mK), concluding that our findings for zero temperature remain qualitatively valid also for 100 mK. We confirm the same anisotropic switch of the axis of prolonged spin lifetime with varying detuning as recently predicted in GaAs. Conditions for possibly hyperfine-dominated relaxation are much more stringent in Si than in GaAs. For experimentally relevant regimes, the spin-orbit coupling, although weak, is the dominant contribution, yielding anisotropic relaxation rates of at least two orders of magnitude lower than in GaAs.

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Section: Introductionmentioning

confidence: 99%

Theory of spin relaxation in two-electron laterally coupled Si/SiGe quantum dots

2012

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“…In all the samples mentioned already, the spin-spin decay time measured with a Hahn echo sequence (T HE 2 ) [34] was about an order of magnitude longer than the FID characteristic time (T * 2 ), evidencing the line inhomogeneity. Magnetization tails have been observed in 29 Si, C 60 and Y 2 O 3 [13,41,42], in adamantane under 1 H decoupling [57] and indirectly in 31 P in EPR experiments [20].…”

Section: Long-lived Signalsmentioning

confidence: 95%

“…From the beginning, it was verified that there is no dependence on the amount of donors or acceptors in the 29 Si polycrystalline sample even when these could change the linewidths and spin-lattice relaxation time by one order of magnitude. Experiments were repeated on 29 Si single crystals and Pyrex, as well as 13 C in C 60 , yielding the same behaviour.…”

Section: Long-lived Signalsmentioning

confidence: 99%

“…Notice that the spin dipolar interactions decay with the cube of the distance and that the gyromagnetic factors of 29 Si and 13 C are approximately one-fifth and one-fourth that of 1 H, rendering 29 Si- 29 Si and 13 C- 13 phase shifts with respect to the first p/2 pulse, respectively), and considering the number of phases (one or two) for the p pulses in each cycle, these sequences were named as follows:…”

Section: Long-lived Signalsmentioning

confidence: 99%

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Storage of quantum coherences as phase-labelled local polarization in solid-state nuclear magnetic resonance

Franzoni

Acosta

Pastawski

et al. 2012

Phil. Trans. R. Soc. A.

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Nuclear spins are promising candidates for quantum information processing because their good isolation from the environment precludes the rapid loss of quantum coherence. Many strategies have been developed to further extend their decoherence times. Some of them make use of decoupling techniques based on the Carr-Purcell and Carr-PurcellMeiboom-Gill pulse sequences. In many cases, when applied to inhomogeneous samples, they yield a magnetization decay much slower than that of the Hahn echo. However, we have proved that these decays cannot be associated with longer decoherence times, as coherences remain frozen. They result from coherences recovered after their storage as local polarization and thus they can be used as memories. We show here how this freezing of the coherent state, which can subsequently be recovered after times longer than the natural decoherence time of the system, can be generated in a controlled way with the use of field gradients. A similar behaviour of homogeneous samples in inhomogeneous fields is demonstrated. It is emphasized that the effects of inhomogeneities in solid-state nuclear magnetic resonance, independently of their origin, should not be disregarded, as they play a crucial role in multipulse sequences.

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“…Employing molecular systems as "quantum hardware" [6,7] offers the advantages of high reproducibility, chemically engineered system properties, and the potential for selfassembly into more complex functional units. In general, nuclear spins are widely considered to be the most promising quantum bits (qubits) for a quantum memory in solid-state systems, since they have remarkably long coherence times [8]. However, they are also hard to manipulate on a fast time scale, as nuclei are usually only weakly coupled.…”

Section: Introductionmentioning

confidence: 99%

Creating nuclear spin entanglement using an optical degree of freedom

2011

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Molecular nanostructures are promising building blocks for future quantum technologies, provided methods of harnessing their multiple degrees of freedom can be identified and implemented. Due to low decoherence rates, nuclear spins are considered ideal candidates for storing quantum information, while optical excitations can give rise to fast and controllable interactions for information processing. A recent paper [M. Schaffry et al., Phys. Rev. Lett. 104, 200501 (2010)] proposed a method for entangling two nuclear spins through their mutual coupling to a transient optically excited electron spin. Building on the same idea, we present here an extended and much more detailed theoretical framework, showing that this method is in fact applicable to a much wider class of molecular structures than previously discussed in the original proposal.

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Coherence time of decoupled nuclear spins in silicon

Cited by 153 publications

References 54 publications

Theory of spin relaxation in two-electron laterally coupled Si/SiGe quantum dots

Theory of spin relaxation in two-electron laterally coupled Si/SiGe quantum dots

Storage of quantum coherences as phase-labelled local polarization in solid-state nuclear magnetic resonance

Creating nuclear spin entanglement using an optical degree of freedom

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