Photon extrabunching in ultrabright twin beams measured by two-photon counting in a semiconductor

For many years twin beams originating from parametric down-converted light beams have aroused great interest and attention in the photonics community. One particular aspect of the twin beams is their peculiar intensity correlation functions, which are related to the coincidence rate of photon pairs....

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Veröffentlicht in:Nature communications 2011-08, Vol.2 (1), p.425-425, Article 425
Hauptverfasser: Boitier, F., Godard, A., Dubreuil, N., Delaye, P., Fabre, C., Rosencher, E.
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Sprache:eng
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Zusammenfassung:For many years twin beams originating from parametric down-converted light beams have aroused great interest and attention in the photonics community. One particular aspect of the twin beams is their peculiar intensity correlation functions, which are related to the coincidence rate of photon pairs. Here we take advantage of the huge bandwidth offered by two-photon absorption in a semiconductor to quantitatively determine correlation functions of twin beams generated by spontaneous parametric down-conversion. Compared with classical incoherent sources, photon extrabunching is unambiguously and precisely measured, originating from exact coincidence between down-converted pairs of photons, travelling in unison. These results strongly establish that two-photon counting in semiconductors is a powerful tool for the absolute measurement of light beam photon correlations at ultrashort timescales. The second order correlation function g (2) is used to test quantum correlation properties of light. Here, two-photon counting is used to measure g (2) and an extrabunching effect is demonstrated, providing evidence that two-photon counting is an appropriate method for measuring light beam photon correlations.
ISSN:2041-1723
2041-1723
DOI:10.1038/ncomms1423