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Generation of nondegenerate narrow-band photon pairs for hybrid quantum network

In a hybrid quantum network, linking two kinds of quantum nodes through photonic channels requires excellent matching of central frequency and bandwidth between both nodes and their interfacing photons. However, pre-existing photon sources can not fulfill this requirement. Using a novel conjoined double-cavity strategy, we report the generation of nondegenerate narrow-band photon pairs by cavity-enhanced spontaneous parametric down-conversion. The central frequencies and bandwidths of the signal and idler photons are independently set to match with trapped ions and solid-state quantum memories. With this source we achieve the bandwidths and central frequencies of 4 MHz at 935 nm and 5 MHz at 880 nm for the signal and idler photons respectively, with a normalized spectrum brightness of 4.9/s/MHz/mW. Due to the ability of being independently locked to two different wavelenghts, the conjoined double-cavity is universally suitable for hybrid quantum network consisting of various quantum nodes.

preprint2015arXivOpen access
Jian WangPeng-YinJie LvJin-Ming CuiBi-Heng LiuJian-Shun TangYun-Feng HuangChuan-Feng LiGuang-Can Guo
quant-ph
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Open access8 authors1 topic
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Jian WangPeng-YinJie LvJin-Ming CuiBi-Heng LiuJian-Shun TangYun-Feng HuangChuan-Feng LiGuang-Can Guo

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