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Nature Milestones are special supplements that aim to highlight the 'milestones' or remarkable achievements in a given field. Each breakthrough is covered in a short Milestone article, written by an editor from the Nature Publishing Group, which discusses landmark discoveries in the context of the prevailing concepts at the time and our current knowledge of the field.
Nature Milestones: Photons is the tenth supplement in the series. It comes 50 years after Theodore Maiman realized, on 16 May 1960, the first laser. But Nature Milestones: Photons intends to reach far beyond Maiman's breakthrough, beginning with early systematic descriptions of light since the 17th century. Still, much of the fundamental understanding of light that we have today is based on its description as an electromagnetic wave, and that it comes in basic 'units' — photons.
Schawlow and Townes1 have proposed a technique for the generation of very monochromatic radiation in the infra-red optical region of the spectrum using an alkali vapour as the active medium. Javan2 and Sanders3 have discussed proposals involving electron-excited gaseous systems. In this laboratory an optical pumping technique has been successfully applied to a fluorescent solid resulting in the attainment of negative temperatures and stimulated optical emission at a wave-length of 6943 Å. ; the active material used was ruby (chromium in corundum).
Quantum teleportation — the transmission and reconstruction over arbitrary distances of the state of a quantum system — is demonstrated experimentally. During teleportation, an initial photon which carries the polarization that is to be transferred and one of a pair of entangled photons are subjected to a measurement such that the second photon of the entangled pair acquires the polarization of the initial photon. This latter photon can be arbitrarily far away from the initial one. Quantum teleportation will be a critical ingredient for quantum computation networks.