Quantum hyperentanglement and its applications in quantum information processing

被引：4

作者：

Fu-Guo Deng ^{[1
]}

Bao-Cang Ren ^{[2
]}

Xi-Han Li ^{[3
,4
]}

机构：

[1] Department of Physics, Applied Optics Beijing Area Major Laboratory, Beijing Normal University

[2] Department of Physics, Capital Normal University

[3] Department of Physics, Chongqing University

[4] Department of Physics and Computer Science, Wilfrid Laurier University

来源：

ScienceBulletin | 2017年 / 62卷 / 01期

基金：

中国国家自然科学基金;

关键词：

Quantum hyperentanglement; High-capacity quantum communication; Concentration and purification; Hyperparallel photonic quantum; computation; Quantum information processing;

D O I：

暂无

中图分类号：

O413 [量子论]; TN918 [通信保密与通信安全];

学科分类号：

070201 ; 0839 ; 1402 ;

摘要：

Hyperentanglement is a promising resource in quantum information processing with its high capacity character, defined as the entanglement in multiple degrees of freedom(DOFs) of a quantum system, such as polarization, spatial-mode, orbit-angular-momentum, time-bin and frequency DOFs of photons.Recently, hyperentanglement attracts much attention as all the multiple DOFs can be used to carry information in quantum information processing fully. In this review, we present an overview of the progress achieved so far in the field of hyperentanglement in photon systems and some of its important applications in quantum information processing, including hyperentanglement generation, complete hyperentangled-Bell-state analysis, hyperentanglement concentration, and hyperentanglement purification for high-capacity long-distance quantum communication. Also, a scheme for hyper-controlled-not gate is introduced for hyperparallel photonic quantum computation, which can perform two controlled-not gate operations on both the polarization and spatial-mode DOFs and depress the resources consumed and the photonic dissipation.

引用

页码：46 / 68

页数：23

共 153 条

[1] Complete hyperentangled-Bell-state analysis for photonic qubits assisted by a three-level Lambda-type system. Wang TJ,Wang C. Science Reports . 2016
[2] Experimental demonstration of a hyper-entangled ten-qubit Schr?dinger cat state[J] . Gao, Wei-bo,Lu, Chao-yang,Yao, Xing-can,Xu, Ping,Gühne, Otfried,Goebel, Alexander,Chen, Yu-ao,Peng, Cheng-zhi,Chen, Zeng-bing,Pan, Jian-wei. &nbspNature Physics . 2010 (5)
[3] Nonlocal hyperconcentration on entangled photons using photonic module system[J] . Cong Cao,Tie-Jun Wang,Si-Chen Mi,Ru Zhang,Chuan Wang. &nbspAnnals of Physics . 2016
[4] 量子集成线路:经典表征（英文）
许金时
李传锋
[J]. ScienceBulletin, 2015, 60 (01) : 141+1 - 141
[5] Heralded entanglement concentration for photon systems with linear-optical elements[J]. DU FangFang,DENG FuGuo. Science China(Physics,Mechanics & Astronomy). 2015(04)
[6] Efficient N-particle W state concentration with different parity check gates[J]. SHENG YuBo,PAN Jun,GUO Rui,ZHOU Lan,WANG Lei. Science China(Physics,Mechanics & Astronomy). 2015(06)
[7] 多用户到多用户的通讯波段纠缠光子分发（英文）
曹冬阳
柳必恒
王钊
黄运锋
李传锋
郭光灿
[J]. ScienceBulletin, 2015, 60 (12) : 1128 - 1132
[8] Hyperentangled Bell-state analysis. Wei, Tzu-Chieh,Barreiro, Julio T,Kwiat, Paul G. Physical Review A - Atomic, Molecular, and Optical Physics . 2007
[9] Resource-efficient linear optical quantum computation. Browne Daniel E,Rudolph Terry. Physical Review . 2005
[10] Hyperconcentration for multipartite entanglement via linear optics. Li X H,Ghose S. Laser Phys Lett . 2014

← 1 2 3 4 5 6 7 8 9 10 →