Direct Structural Identification and Quantification of the Split-Vacancy Configuration for Implanted Sn in Diamond.

We demonstrate formation of the ideal split-vacancy configuration of the Sn-vacancy center upon implantation into natural diamond. Using ß^{-} emission channeling following low fluence ^{121}Sn implantation (2×10^{12} atoms/cm^{2}, 60 keV) at the ISOLDE facility at CERN, we directly identified and quantified the atomic configurations of the Sn-related centers. Our data show that the split-vacancy configuration is formed immediately upon implantation with a surprisingly high efficiency of ≈40%. Upon thermal annealing at 920 °C ≈30% of Sn is found in the ideal bond-center position. Photoluminescence revealed the characteristic SnV^{-} line at 621 nm, with an extraordinarily narrow ensemble linewidth (2.3 nm) of near-perfect Lorentzian shape. These findings further establish the SnV^{-} center as a promising candidate for single photon emission applications, since, in addition to exceptional optical properties, it also shows a remarkably simple structural formation mechanism.

Photoelectric detection of electron spin resonance of nitrogen-vacancy centres in diamond.

The readout of negatively charged nitrogen-vacancy centre electron spins is essential for applications in quantum computation, metrology and sensing. Conventional readout protocols are based on the detection of photons emitted from nitrogen-vacancy centres, a process limited by the efficiency of photon collection. We report on an alternative principle for detecting the magnetic resonance of nitrogen-vacancy centres, allowing the direct photoelectric readout of nitrogen-vacancy centres spin state in an all-diamond device. The photocurrent detection of magnetic resonance scheme is based on the detection of charge carriers promoted to the conduction band of diamond by two-photon ionization of nitrogen-vacancy centres. The optical and photoelectric detection of magnetic resonance are compared, by performing both types of measurements simultaneously. The minima detected in the measured photocurrent at resonant microwave frequencies are attributed to the spin-dependent ionization dynamics of nitrogen-vacancy, originating from spin-selective non-radiative transitions to the metastable singlet state.

Aberrations in the diurnal rhythms of plasma glucose, plasma insulin, liver glycogen, and hepatic glycogen synthase and phosphorylase activities in genetically diabetic (db/db) mice.

The diurnal rhythms of plasma glucose, insulin, liver glycogen, and hepatic glycogen synthase and phosphorylase activities were determined in control and genetically diabetic (db/db) mice 8 weeks of age. The diabetic mice showed wide fluctuations in their plasma glucose levels, although being similar to controls near the end of the light period. Little variation was observed in their elevated plasma insulin levels. Liver glycogen levels in diabetic mice were not depleted to the low levels seen in controls during the last part of the light period but were maintained at significantly higher levels. However, maximum attained glycogen levels were similar in the two groups of mice. Alterations were also observed for the diurnal rhythms of glycogen synthase and phosphorylase activities, although again the daily maximums were similar in control and diabetic mice. These findings suggest that the reported changes of several of these metabolic parameters in the db/db mouse may be due to alterations in the diurnal pattern rather than to absolute changes.