of entangled photon pairs has been directly measured. In the early days of quantum mechanics, Louis de Broglie argued, and it was soon demonstrated, that if waves could act like particles (as in the photoelectric effect), then particles could also act like waves. By now, the wave nature of molecules as large as buckyballs (carbon-60) has been demonstrated. For composite objects, the de Broglie wavelength depends fundamentally on the object’s internal structure. For an ensemble of photons taken collectively, the de Broglie wavelength is λ/N, the wavelength of an individual photon divided by the number of photons. This was verified in 1999 for a two-photon wavepacket in a double-slit experiment. Physicists at Osaka University in Japan have now demonstrated that the relation still holds for spatially separated, entangled photons. Through parametric down-conversion, they transformed a photon of wavelength λ into an entangled pair of photons (a biphoton) of wavelength...
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1 January 2003
January 01 2003
Citation
Phil F. Schewe; The photonic de Broglie wavelength. Physics Today 1 January 2003; 56 (1): 9. https://doi.org/10.1063/1.4796891
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