Shota Yokoyama, Ryuji Ukai, Seiji C. Armstrong, Chanond Sornphiphatphong, Toshiyuki Kaji, Shigenari Suzuki, Jun-ichi Yoshikawa, Hidehiro Yonezawa, Nicolas C. Menicucci, Akira Furusawa
Entanglement is a uniquely quantum phenomenon and a physical resource that can be used for quantum information processing. Cluster states are multipartite states with an entanglement structure that is robust to local measurements and can be used for measurement-based quantum computation. To date, the largest optically generated cluster state consists of 8 entangled qubits, while the largest multipartite entangled state of any sort to date involves 14 trapped ions. These implementations consist of quantum entities separated in space, and in general each experimental apparatus is used only once. This inherent inefficiency prohibits the generation of larger entangled states due to the experimental setup requiring additional components as the state grows. Here, we report the experimental generation and full characterisation of an ultra-large-scale entangled state containing more than 10,000 entangled modes that is equivalent to a continuous-variable cluster state up to local phase shifts. This is an improvement by 3 orders of magnitude over the largest entangled states created to date. The entangled modes are individually addressable, finite-duration wavepackets of light in two beams that are multiplexed in the time domain and created deterministically. Our ultra-large-scale entangled states are an important contribution to investigations of quantum information processing.
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http://arxiv.org/abs/1306.3366
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