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Chemical control of the charge state of nitrogen-vacancy centers in diamond

We investigate the effect of surface termination on the charge state of nitrogen vacancy centers, which have been ion-implanted few nanometers below the surface of diamond. We find that, when changing the surface termination from oxygen to hydrogen, previously stable NV- centers convert into NV0 and, subsequently, into an unknown non-fluorescent state. This effect is found to depend strongly on the implantation dose. Simulations of the electronic band structure confirm the dissappearance of NV- in the vicinity of the hydrogen-terminated surface. The band bending, which induces a p-type surface conductive layer leads to a depletion of electrons in the nitrogen vacancies close to the surface. Therefore, hydrogen surface termination provides a chemical way for the control of the charge state of nitrogen-vacancy centers in diamond. Furthermore, it opens the way to an electrostatic control of the charge state with the use of an external gate electrode.

preprint2010arXivOpen access
M. V. HaufB. GrotzB. NaydenovM. DankerlS. PezzagnaJ. MeijerF. JelezkoJ. WrachtrupM. StutzmannF. ReinhardJ. A. Garrido
cond-mat.mtrl-sciquant-ph
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Open access11 authors2 topics
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M. V. HaufB. GrotzB. NaydenovM. DankerlS. PezzagnaJ. MeijerF. JelezkoJ. WrachtrupM. StutzmannF. ReinhardJ. A. Garrido

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