2012
DOI: 10.1038/ncomms1637
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Electrically driven photon antibunching from a single molecule at room temperature

Abstract: single-photon emitters have been considered for applications in quantum information processing, quantum cryptography and metrology. For the sake of integration and to provide an electron photon interface, it is of great interest to stimulate single-photon emission by electrical excitation as demonstrated for quantum dots. Because of low exciton binding energies, it has so far not been possible to detect sub-Poissonian photon statistics of electrically driven quantum dots at room temperature. However, organic m… Show more

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Cited by 73 publications
(69 citation statements)
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“…In comparison to Eq. (1), the anomalous dip observed at τ ∼ 0 is satisfactorily reproduced with theg (2) (τ) as indicated by the red line in Fig. 1 (b).…”
supporting
confidence: 61%
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“…In comparison to Eq. (1), the anomalous dip observed at τ ∼ 0 is satisfactorily reproduced with theg (2) (τ) as indicated by the red line in Fig. 1 (b).…”
supporting
confidence: 61%
“…1 (b). Therefore, it is essential to employ theg (2) Generalized intensity autocorrelation function presented in this work is applicable to the whole T rep /τ e range, which is essential to precisely evaluate the α 0 under arbitrary operating conditions. Note that the fine fitting for the height of each correlation peak at τ = n·T rep (|n| ≥ 1) shown in Fig.…”
mentioning
confidence: 99%
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“…For many of these applications it is necessary to have control over single emitters with long spin coherence times. Such single quantum systems have been realized using quantum dots 6 , colour centres in diamond 7 , dopants in nanostructures 8 and molecules 9 . More recently, ensemble emitters with spin dephasing times in the order of microseconds and room-temperature optically detectable magnetic resonance (ODMR) have been identified in silicon carbide (SiC) [10][11][12] , a compound being highly compatible to up-to-date semiconductor device technology.…”
mentioning
confidence: 99%