Time–energy high-dimensional one-side device-independent quantum key distribution  

作　　者：包海泽 鲍皖苏 汪洋 陈瑞柯 马鸿鑫 周淳 李宏伟 

机构地区：[1]Zhengzhou Information Science and Technology Institute, Zhengzhou 450001, China [2]Synergetic Innovation Center of Quantum Information and Quantum Physics, University of Science and Technology of China, Hefei 230026, China

出　　处：《Chinese Physics B》2017年第5期60-65,共6页中国物理B（英文版）

基　　金：Project supported by the National Basic Research Program of China(Grant No.2013CB338002);the National Natural Science Foundation of China(Grants Nos.11304397 and 61505261)

摘　　要：Compared with full device-independent quantum key distribution（DI-QKD）, one-side device-independent QKD（1s DI-QKD） needs fewer requirements, which is much easier to meet. In this paper, by applying recently developed novel time–energy entropic uncertainty relations, we present a time–energy high-dimensional one-side device-independent quantum key distribution（HD-QKD） and provide the security proof against coherent attacks. Besides, we connect the security with the quantum steering. By numerical simulation, we obtain the secret key rate for Alice＇s different detection efficiencies. The results show that our protocol can performance much better than the original 1s DI-QKD. Furthermore, we clarify the relation among the secret key rate, Alice＇s detection efficiency, and the dispersion coefficient. Finally, we simply analyze its performance in the optical fiber channel.Compared with full device-independent quantum key distribution（DI-QKD）, one-side device-independent QKD（1s DI-QKD） needs fewer requirements, which is much easier to meet. In this paper, by applying recently developed novel time–energy entropic uncertainty relations, we present a time–energy high-dimensional one-side device-independent quantum key distribution（HD-QKD） and provide the security proof against coherent attacks. Besides, we connect the security with the quantum steering. By numerical simulation, we obtain the secret key rate for Alice＇s different detection efficiencies. The results show that our protocol can performance much better than the original 1s DI-QKD. Furthermore, we clarify the relation among the secret key rate, Alice＇s detection efficiency, and the dispersion coefficient. Finally, we simply analyze its performance in the optical fiber channel.

关 键 词：secret coherent proof steering coincidence Time Alice applying uncertainty entangled 

分 类 号：O413[理学—理论物理] TN918.4[理学—物理]