Phase Memory in Electron Spin Echoes, Lattice Relaxation Effects in CaW<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:mrow><mml:msub><mml:mrow><mml:mi mathvariant="normal">O</mml:mi></mml:mrow><mml:mrow><mml:mn>4</mml:mn></mml:mrow></mml:msub></mml:mrow></mml:math>: Er, Ce, Mn

Mims, W. B.

doi:10.1103/physrev.168.370

Cited by 272 publications

(143 citation statements)

References 12 publications

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“…2(B) shows a distinctly different temperature dependence of T 2 from Samples A and C. At high and low temperatures, T 2 approaches 0.7 ms, close to that in Samples A and C. However, T 2 drops down at intermediate temperatures reaching a minimum of 0.45 ms (a 35% reduction) at around 15 K. This type of T 2 temperature dependence has been observed in situations where thermally activated electric or magnetic field noise dominates spin relaxation. [31][32][33] As temperature decreases the characteristic time of this noise (τ c ) increases, making a transition from a motional narrowing regime (τ c ≪ T 2 ) at high temperatures to a slow spectral diffusion regime (τ c ≫ T 2 ) at low temperatures. The effect of noise is minimal in these two extreme regimes (therefore long T 2 ), however the effect on T 2 can become significant in the intermediate regime when…”

Section: A Nvmentioning

confidence: 99%

Spin coherence and 14 N ESEEM effects of nitrogen-vacancy centers in diamond with X-band pulsed ESR

Rose

Weis

Tyryshkin

et al. 2017

Diamond and Related Materials

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Pulsed ESR experiments are reported for ensembles of negatively-charged nitrogen-vacancy centers (NV − ) in diamonds at X-band magnetic fields (280-400 mT) and low temperatures (2-70 K). The NV − centers in synthetic type IIb diamonds (nitrogen impurity concentration < 1 ppm) are prepared with bulk concentrations of 2 · 10 13 cm −3 to 4 · 10 14 cm −3 by high-energy electron irradiation and subsequent annealing. We find that a proper post-radiation anneal (1000• C for 60 mins) is critically important to repair the radiation damage and to recover long electron spin coherence times for NV − s. After the annealing, spin coherence times of T2 = 0.74 ms at 5 K are achieved, being only limited by 13 C nuclear spectral diffusion in natural abundance diamonds. At X-band magnetic fields, strong electron spin echo envelope modulation (ESEEM) is observed originating from the central 14 N nucleus. The ESEEM spectral analysis allows for accurate determination of the 14 N nuclear hypefine and quadrupole tensors. In addition, the ESEEM effects from two proximal 13 C sites (second-nearest neighbor and fourth-nearest neighbor) are resolved and the respective 13 C hyperfine coupling constants are extracted.

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Section: A Nvmentioning

confidence: 99%

Spin coherence and 14 N ESEEM effects of nitrogen-vacancy centers in diamond with X-band pulsed ESR

Rose

Weis

Tyryshkin

et al. 2017

Diamond and Related Materials

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“…55,61,62 The "true" T 2 of isolated donors extrapolates to about 60 ms, e.g. after suppressing the instantaneous diffusion.…”

Section: 60mentioning

confidence: 99%

Effect of pulse error accumulation on dynamical decoupling of the electron spins of phosphorus donors in silicon

et al. 2012

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Dynamical decoupling (DD) is an efficient tool for preserving quantum coherence in solid-state spin systems. However, the imperfections of real pulses can ruin the performance of long DD sequences. We investigate the accumulation and compensation of different pulse errors in DD using the electron spins of phosphorus donors in silicon as a test system. We study periodic DD sequences (PDD) based on spin rotations about two perpendicular axes, and their concatenated and symmetrized versions. We show that pulse errors may quickly destroy some spin states, but maintain other states with high fidelity over long times. Pulse sequences based on spin rotations about x and y axes outperform those based on x and z axes due to the accumulation of pulse errors. Concatenation provides an efficient way to suppress the impact of pulse errors, and can maintain high fidelity for all spin components: pulse errors do not accumulate (to first order) as the concatenation level increases, despite the exponential increase in the number of pulses. A symmetrized DD sequence cancels the first order pulse errors. Our theoretical model gives a clear qualitative picture of the error accumulation, and produces results in quantitative agreement with the experiments.

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“…Below 160K, the CS 2 solvent freezes as a polycrystal, leaving regions of high fullerene concentration around grain boundaries. This dramatically increases the local spin concentration, and T 2 becomes extremely short due to dipolar spin coupling (the so-called instantaneous diffusion effect [12,13,14]). …”

Section: Relaxation Of N@c60 In Cs2mentioning

confidence: 99%

Electron spin relaxation of N@C60 in CS2

Morton

Tyryshkin

Ardavan

et al. 2006

The Journal of Chemical Physics

110

127

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We examine the temperature dependence of the electron spin relaxation times of the molecules N@C60 and N@C70 (which comprise atomic nitrogen trapped within a carbon cage) in liquid CS2 solution. The results are inconsistent with the fluctuating zero field splitting (ZFS) mechanism, which is commonly invoked to explain electron spin relaxation for S ≥ 1 spins in liquid solution, and is the mechanism postulated in the literature for these systems. Instead, we find an Arrhenius temperature dependence for N@C60, indicating the spin relaxation is driven primarily by an Orbach process. For the asymmetric N@C70 molecule, which has a permanent ZFS, we resolve an additional relaxation mechanism caused by the rapid reorientation of its ZFS. We also report the longest coherence time (T2) ever observed for a molecular electron spin, being 0.25 ms at 170K.

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Phase Memory in Electron Spin Echoes, Lattice Relaxation Effects in CaWO4: Er, Ce, Mn

Cited by 272 publications

References 12 publications

Spin coherence and 14 N ESEEM effects of nitrogen-vacancy centers in diamond with X-band pulsed ESR

Spin coherence and 14 N ESEEM effects of nitrogen-vacancy centers in diamond with X-band pulsed ESR

Effect of pulse error accumulation on dynamical decoupling of the electron spins of phosphorus donors in silicon

Electron spin relaxation of N@C60 in CS2

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