Super-resolving phase measurements with a multiphoton entangled state

Abstract

Interference phenomena are ubiquitous in physics, often forming the basis of demanding measurements. Examples include Ramsey interferometry in atomic spectroscopy, X-ray diffraction in crystallography and optical interferometry in gravitational-wave studies^1,2. It has been known for some time that the quantum property of entanglement can be exploited to perform super-sensitive measurements, for example in optical interferometry or atomic spectroscopy^3,4,5,6,7. The idea has been demonstrated for an entangled state of two photons⁸, but for larger numbers of particles it is difficult to create the necessary multiparticle entangled states^9,10,11. Here we demonstrate experimentally a technique for producing a maximally entangled three-photon state from initially non-entangled photons. The method can in principle be applied to generate states of arbitrary photon number, giving arbitrarily large improvement in measurement resolution^12,13,14,15. The method of state construction requires non-unitary operations, which we perform using post-selected linear-optics techniques similar to those used for linear-optics quantum computing^{16,17,18,19,20}.