Nitrogen impurities help to stabilize the negatively-charged-state of NV$^-$ in diamond, whereas magnetic fluctuations from nitrogen spins lead to decoherence of NV$^-$ qubits. It is not known what donor concentration optimizes these conflicting requ
irements. Here we used 10-MeV $^{15}$N$^{3+}$ ion implantation to create NV$^-$ in ultrapure diamond. Optically detected magnetic resonance of single centers revealed a high creation yield of $40pm3$% from $^{15}$N$^{3+}$ ions and an additional yield of $56pm3$% from $^{14}$N impurities. High-temperature anneal was used to reduce residual defects, and charge stable NV$^-$, even in a dilute $^{14}$N impurity concentration of 0.06 ppb were created with long coherence times.
We have searched for neutrinoless $tau$ lepton decays into $ell$ and $V^0$, where $ell$ stands for an electron or muon, and $V^0$ for a vector meson ($phi$, $omega$, $K^{*0}$, $bar{K}^{*0}$ or $rho^0$), using 543 fb$^{-1}$ of data collected with the
Belle detector at the KEKB asymmetric-energy $e^+e^-$ collider. No excess of signal events over the expected background has been observed, and we set upper limits on the branching fractions in the range $(5.9-18) times 10^{-8}$ at the 90% confidence level. These upper limits include the first results for the $ell omega$ mode as well as new limits that are significantly more restrictive than our previous results for the $ell phi$, $ell K^{*0}$, $ell bar{K}^{*0}$ and $ell rho^0$ modes.
