## Publication in Nature Materials

We are proud to announce that our publication *„Solid-state electron spin lifetime limited by phononic vacuum modes“* was published in Nature Materials on February 12th 2018.

### Solid-state electron spin lifetime limited by phononic vacuum modes

We investigate on the fundamental mechanism of spin phonon coupling in the negatively charged nitrogen vacancy center (NV−) in diamond in order to calculate the spin lattice relaxation time T1 and its temperature dependence ab initio. Starting from the dipolar spin-spin interaction between two electrons, we couple the spins of the electron to the movements of the ions and end up with an eﬀective spin-phonon interaction potential Vs−ph. Taking this time dependent potential as a perturbation of the system leads to Fermi’s golden rule for transition rates which allow to calculate the spin lattice relaxation time T1. We simulate the color center with the Vienna Ab Initio Simulation Package (VASP) to extract the ﬁgures necessary to quantify T1: First, we obtain the equilibrium positions of the ions and the electronic charge density by a proper relaxation of the system. Next, we investigate on the local phonon modes of the color center within the harmonic approximation using the small displacement method. We extract the phononic density of states and bandstructure by diagonalizing the dynamical matrix using the phononpy package. Then, we model the electronic wavefunctions by calculating maximally localized Wannier functions with Wannier90 and building the orbitals according to the C3v symmetry of the defect. Finally, we plug the simulated ﬁgures into our model and end up with a calculated relaxation time T1 that is very close to the experimental observations.

Original publication: T. Astner, J. Gugler, A. Angerer, S. Wald, S. Putz, N. J. Mauser, M. Trupke, H. Sumiya, S. Onoda, J. Isoya, J. Schmiedmayer, P. Mohn, and J. Majer.