Optimized nonadiabatic holonomic quantum computation based on Förster resonance in Rydberg atoms 被引量：1

导出

摘要 In this paper,we propose a scheme for implementing the nonadiabatic holonomic quantum computation(NHQC+)of two Rydberg atoms by using invariant-based reverse engineering(IBRE).The scheme is based on Förster resonance induced by strong dipole-dipole interaction between two Rydberg atoms,which provides a selective coupling mechanism to simply the dynamics of system.Moreover,for improving the fidelity of the scheme,the optimal control method is introduced to enhance the gate robustness against systematic errors.Numerical simulations show the scheme is robust against the random noise in control fields,the deviation of dipole-dipole interaction,the Förster defect,and the spontaneous emission of atoms.Therefore,the scheme may provide some useful perspectives for the realization of quantum computation with Rydberg atoms.

作者 Shuai Liu Jun-Hui Shen Ri-Hua Zheng Yi-Hao Kang Zhi-Cheng Shi Jie Song Yan Xia

机构地区 Fujian Key Laboratory of Quantum Information and Quantum Optics(Fuzhou University) Department of Physics School of Rail Transportation Department of Physics

出处《Frontiers of physics》 SCIE CSCD 2022年第2期57-69,共13页 物理学前沿（英文版）

基金 supported by the National Natural Science Foundation of China under Grant Nos 11575045,11874114,and 11674060 the Natural Science Funds for Distinguished Young Scholar of Fujian Province under Grant 2020J06011 Project from Fuzhou University under Grant JG202001-2.

关键词 nonadiabatic holonomic quantum computation reverse engineering Förster resonance

分类号 O31 [理学—一般力学与力学基础]

引文网络
相关文献

参考文献5

1You-Ji Fan,Zhen-Fei Zheng,Yu Zhang,Dao-Ming Lu,Chui-Ping Yang.One-step implementation of a multi-target-qubit controlled phase gate with cat-state qubits in circuit QED[J].Frontiers of physics,2019,14(2):13-21. 被引量：7
2Heng Fan,Xiaobo Zhu.12 superconducting qubits for quantum walks[J].Frontiers of physics,2019,14(6):1-2. 被引量：1
3Sai Li,Pu Shen,Tao Chen,Zheng-Yuan Xue.Noncyclic nonadiabatic holonomic quantum gates via shortcuts to adiabaticity[J].Frontiers of physics,2021,16(5):39-46. 被引量：3
4Jing Xu,Sai LI,Tao Chen,Zheng-Yuan Xue.Nonadiabatic geometric quantum computation with optimal control on superconducting circuits[J].Frontiers of physics,2020,15(4):17-24. 被引量：7
5Xiao-Feng Shi.Rydberg quantum computation with nuclear spins in two-electron neutral atoms[J].Frontiers of physics,2021,16(5):21-38. 被引量：3

二级参考文献7

1Hang Li,Yang Liu,GuiLu Long.Experimental realization of single-shot nonadiabatic holonomic gates in nuclear spins[J].Science China(Physics,Mechanics & Astronomy),2017,60(8):1-7. 被引量：5
2M. AbuGhanem,A. H. Homid,M. Abdel-Aty.Cavity control as a new quantum algorithms implementation treatment[J].Frontiers of physics,2018,13(1):187-199. 被引量：2
3Gaurav Bhole,Jonathan A. Jones.Practical pulse engineering： Gradient ascent without matrix exponentiation[J].Frontiers of physics,2018,13(3):3-8. 被引量：2
4You-Ji Fan,Zhen-Fei Zheng,Yu Zhang,Dao-Ming Lu,Chui-Ping Yang.One-step implementation of a multi-target-qubit controlled phase gate with cat-state qubits in circuit QED[J].Frontiers of physics,2019,14(2):13-21. 被引量：7
5Xing-Yan Chen,Tongcang Li,Zhang-Qi Yin.Nonadiabatic dynamics and geometric phase of an ultrafast rotating electron spin[J].Science Bulletin,2019,64(6):380-384. 被引量：2
6Xiao-Tao Mo,Zheng-Yuan Xu.Single-step multipartite entangled states generation from coupled circuit cavities[J].Frontiers of physics,2019,14(3):115-121. 被引量：5
7Jing Xu,Sai LI,Tao Chen,Zheng-Yuan Xue.Nonadiabatic geometric quantum computation with optimal control on superconducting circuits[J].Frontiers of physics,2020,15(4):17-24. 被引量：7

共引文献15

1Xiao-Tao Mo,Zheng-Yuan Xu.Single-step multipartite entangled states generation from coupled circuit cavities[J].Frontiers of physics,2019,14(3):115-121. 被引量：5
2范有机,卢道明.有心结构耦合腔系统中的几何量子失谐（英文）[J].光子学报,2020,49(2):74-83.
3Tong Liu,Zhen-Fei Zheng,Yu Zhang,Yu-Liang Fang,Chui-Ping Yang.Transferring entangled states of photonic cat-state qubits in circuit QED[J].Frontiers of physics,2020,15(2):27-37. 被引量：4
4Jing Xu,Sai LI,Tao Chen,Zheng-Yuan Xue.Nonadiabatic geometric quantum computation with optimal control on superconducting circuits[J].Frontiers of physics,2020,15(4):17-24. 被引量：7
5Sai Li,Pu Shen,Tao Chen,Zheng-Yuan Xue.Noncyclic nonadiabatic holonomic quantum gates via shortcuts to adiabaticity[J].Frontiers of physics,2021,16(5):39-46. 被引量：3
6张娜娜,陶明杰,何宛亭,陈鑫宇,孔祥宇,邓富国,Neill Lambert,艾清.Efficient quantum simulation of open quantum dynamics at various Hamiltonians and spectral densities[J].Frontiers of physics,2021,16(5):47-60. 被引量：2
7Qi-Ping Su,Hanyu Zhang,Chui-Ping Yang.Transferring quantum entangled states between multiple single-photon-state qubits and coherent-state qubits in circuit QED[J].Frontiers of physics,2021,16(6):99-108. 被引量：2
8Hanxiao Zhang,Jinhui Wu,M.Artoni,G.C.La Rocca.Single-photon-level light storage with distributed Rydberg excitations in cold atoms[J].Frontiers of physics,2022,17(2):25-32.
9Jin-Lei Wu,Yan Wang,Jin-Xuan Han,Shi-Lei Su,Yan Xia,Yongyuan Jiang,Jie Song.Unselective ground-state blockade of Rydberg atoms for implementing quantum gates[J].Frontiers of physics,2022,17(2):33-45.
10Fu-Quan Dou,Yuan-Jin Wang,Jian-An Sun.Highly efficient charging and discharging of three-level quantum batteries through shortcuts to adiabaticity[J].Frontiers of physics,2022,17(3):101-109.

同被引文献2

1王亮伟,石兢.Quantum fluctuation and interference effect in a single atom-cavity QED system driven by a broadband squeezed vacuum[J].Chinese Optics Letters,2020,18(12):78-82. 被引量：2
2Yexiong Zeng,Biao Xiong,Chong Li.Suppressing laser phase noise in an optomechanical system[J].Frontiers of physics,2022,17(1):59-69. 被引量：2

引证文献1

1Dong-Liang Chen,Ye-Hong Chen,Yang Liu,Zhi-Cheng Shi,Jie Song,Yan Xia.Detecting a single atom in a cavity using the χ^((2)) nonlinear medium[J].Frontiers of physics,2022,17(5):197-205.

1JinLei Wu,Shuai Tang,Yan Wang,XiaoSai Wang,JinXuan Han,Cheng Lü,Jie Song,ShiLei Su,Yan Xia,YongYuan Jiang.Unidirectional acoustic metamaterials based on nonadiabatic holonomic quantum transformations[J].Science China(Physics,Mechanics & Astronomy),2022,65(2):30-38.
2Jin-Lei Wu,Yan Wang,Jin-Xuan Han,Shi-Lei Su,Yan Xia,Yongyuan Jiang,Jie Song.Unselective ground-state blockade of Rydberg atoms for implementing quantum gates[J].Frontiers of physics,2022,17(2):33-45.
3Guofu Xu.A bridge between acoustic metamaterials and quantum computation[J].Science China(Physics,Mechanics & Astronomy),2022,65(4):120-120.
4Junyi Liu,Zi Li,Xu Zhang,Gang Lu.Unraveling energy and charge transfer in type-II van der Waals heterostructures[J].npj Computational Materials,2021(1):1774-1782.
5Daryl Ryan Chong,Minhyuk Kim,Jaewook Ahn,Heejeong Jeong.Erratum to: Machine learning identification of symmetrized base states of Rydberg atoms[J].Frontiers of physics,2022,17(1):57-57.
6Sai Li,Pu Shen,Tao Chen,Zheng-Yuan Xue.Noncyclic nonadiabatic holonomic quantum gates via shortcuts to adiabaticity[J].Frontiers of physics,2021,16(5):39-46. 被引量：3
7张祥,吕昭征,杨光,李冰,侯延亮,乐天,王翔,王安琪,孙晓培,卓恩娜,刘广同,沈洁,屈凡明,吕力.Anomalous Josephson Effect in Topological Insulator-Based Josephson Trijunction[J].Chinese Physics Letters,2022,39(1):31-35.
8铁璐,薛具奎.The Anisotropy of Dipolar Condensate in One-Dimensional Optical Lattices[J].Chinese Physics Letters,2012,29(2):13-16.
9Daryl Ryan Chong,Minhyuk Kim,Jaewook Ahn,Heejeong Jeong.Machine learning identification of symmetrized base states of Rydberg atoms[J].Frontiers of physics,2022,17(1):39-55. 被引量：1
10Heedae Kim,Kwangseuk Kyhm,Robert A.Taylor,Jong Su Kim,Jin Dong Song,Sungkyun Park.Optical shaping of the polarization anisotropy in a laterally coupled quantum dot dimer[J].Light(Science & Applications),2020,9(1):1047-1056.

Frontiers of physics

2022年第2期

浏览历史

内容加载中请稍等...