CAS Key Laboratory of Quantum Information, University of Science and Technology of China, Hefei 230026, People's Republic of China.
Synergetic Innovation Center of Quantum Information and Quantum Physics, University of Science and Technology of China, Hefei 230026, People's Republic of China.
Phys Rev Lett. 2018 Jun 29;120(26):260501. doi: 10.1103/PhysRevLett.120.260501.
We report the experimental measurement of the winding number in an unitary chiral quantum walk. Fundamentally, the spin-orbit coupling in discrete time quantum walks is implemented via a birefringent crystal collinearly cut based on a time-multiplexing scheme. Our protocol is compact and avoids extra loss, making it suitable for realizing genuine single-photon quantum walks at a large scale. By adopting a heralded single photon as the walker and with a high time resolution technology in single-photon detection, we carry out a 50-step Hadamard discrete-time quantum walk with high fidelity up to 0.948±0.007. Particularly, we can reconstruct the complete wave function of the walker that starts the walk in a single lattice site through the local tomography of each site. Through a Fourier transform, the wave function in quasimomentum space can be obtained. With this ability, we propose and report a method to reconstruct the eigenvectors of the system Hamiltonian in quasimomentum space and directly read out the winding numbers in different topological phases (trivial and nontrivial) in the presence of chiral symmetry. By introducing nonequivalent time frames, we show that whole topological phases in a periodically driven system can also be characterized by two different winding numbers. Our method can also be extended to the high winding number situation.
我们报告了在幺正手征量子漫步中涡旋数的实验测量。从根本上说,离散时间量子漫步中的自旋轨道耦合是通过基于时分复用方案的共线切割双折射晶体来实现的。我们的方案紧凑且避免了额外的损耗,使其适用于在大规模上实现真正的单光子量子漫步。通过采用被标记的单光子作为漫步者,并在单光子探测中采用高时间分辨率技术,我们实现了 50 步的 Hadamard 离散时间量子漫步,保真度高达 0.948±0.007。特别地,我们可以通过对每个站点的局部层析成像来重建从单个晶格站点开始的漫步者的完整波函数。通过傅里叶变换,可以得到准动量空间中的波函数。通过这种能力,我们提出并报告了一种在存在手征对称性的情况下在准动量空间中重建系统哈密顿量本征向量并直接读取不同拓扑相(平凡和非平凡)中涡旋数的方法。通过引入不等价的时间帧,我们表明周期性驱动系统中的整个拓扑相也可以用两个不同的涡旋数来描述。我们的方法也可以扩展到高涡旋数的情况。
