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典型文献
Nonadiabatic geometric quantum computation protected by dynamical decoupling via the XXZ Hamiltonian
文献摘要:
Nonadiabatic geometric quantum computation protected by dynamical decoupling combines the ro-bustness of nonadiabatic geometric gates and the decoherence-resilience feature of dynamical decou-pling.Solid-state systems provide an appealing candidate for the realization of nonadiabatic geometric quantum computation protected dynamical decoupling since the solid-state qubits are easily embedded in electronic circuits and scaled up to large registers.In this paper,we put forward a scheme of nonadi-abatic geometric quantum computation protected by dynamical decoupling via the XXZ Hamiltonian,which not only combines the merits of nonadiabatic geometric gates and dynamical decoupling but also can be realized in a number of solid-state systems,such as superconducting circuits and quantum dots.
文献关键词:
作者姓名:
X.Wu;P.Z.Zhao
作者机构:
Department of Physics,Shandong University,Jinan 250100,China
文献出处:
引用格式:
[1]X.Wu;P.Z.Zhao-.Nonadiabatic geometric quantum computation protected by dynamical decoupling via the XXZ Hamiltonian)[J].物理学前沿,2022(03):111-119
A类:
decou,nonadi,abatic
B类:
Nonadiabatic,geometric,quantum,computation,protected,by,dynamical,decoupling,via,XXZ,Hamiltonian,combines,bustness,nonadiabatic,gates,decoherence,resilience,feature,Solid,state,systems,provide,appealing,candidate,realization,since,solid,qubits,are,easily,embedded,electronic,circuits,scaled,large,registers,In,this,paper,we,forward,scheme,which,not,only,merits,but,also,realized,number,such,superconducting,dots
AB值:
0.462439
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