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Ultrafast electronic read-out of diamond NV centers coupled to graphene

Nonradiative transfer processes are often regarded as loss channels for an optical emitter1, since they are inherently difficult to be experimentally accessed. Recently, it has been shown that emitters, such as fluorophores and nitrogen vacancy centers in diamond, can exhibit a strong nonradiative energy transfer to graphene. So far, the energy of the transferred electronic excitations has been considered to be lost within the electron bath of the graphene. Here, we demonstrate that the trans-ferred excitations can be read-out by detecting corresponding currents with picosecond time resolution. We electrically detect the spin of nitrogen vacancy centers in diamond electronically and con-trol the nonradiative transfer to graphene by electron spin resonance. Our results open the avenue for incorporating nitrogen vacancy centers as spin qubits into ultrafast electronic circuits and for harvesting non-radiative transfer processes electronically.

preprint2014arXivOpen access
Andreas BrenneisLouis GaudreauMax SeifertHelmut KarlMartin S. BrandtHans HueblJose A. GarridoFrank H. L. KoppensAlexander W. Holleitner
cond-mat.mes-hallphysics.opticsquant-ph
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Open access9 authors3 topics
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Andreas BrenneisLouis GaudreauMax SeifertHelmut KarlMartin S. BrandtHans HueblJose A. GarridoFrank H. L. KoppensAlexander W. Holleitner

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