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Research progress of material, physics, and device of topological superconductors for quantum computing

Jiang Da Yu Dong-Yang Zheng Zhan Cao Xiao-Chao Lin Qiang Liu Wu-Ming

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Research progress of material, physics, and device of topological superconductors for quantum computing

Jiang Da, Yu Dong-Yang, Zheng Zhan, Cao Xiao-Chao, Lin Qiang, Liu Wu-Ming
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  • Since the physical limit of Moore's law is being approached, many alternative computing methods have been proposed, among which quantum computing is the most concerned and widely studied. Owing to the non closeability of quantum system, the uncontrollable external factors will lead to quantum dissipation and decoherence. In order to avoid the decoherence of quantum superposition state, the fabrication of robust quantum bits has become one of the key factors. Majorana zero mode (MZM) is a quasi-particle emerging in the topological and superconducting hybrid system. It has non-Abelian statistical properties. Therefore, the topological qubit constructed by MZM has natural robustness to quantum decoherence. Despite the arduous exploration by various experimental groups, the experimental verification of MZM is still lacking. This paper reviews the history and main technical routes of quantum computing, focusing on the theory of topological superconductors, observable experimental phenomena, and the latest experimental progress. Furthermore we discuss and analyze the present status of the topological superconductor research. Finally, we prospect the future experiments and applications of topological superconductors in quantum computing.
      Corresponding author: Lin Qiang, qlin@zjut.edu.cn ; Liu Wu-Ming, wmliu@aphy.iphy.ac.cn
    • Funds: Project supported by the National Natural Science Foundation of China (Grant Nos. 61727821, U20A20219, 61835013), and the National Key R&D Program of China (Grants Nos. 2021YFA1400900, 2021YFA0718300, 2021YFA1400243).
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  • 图 1  经典比特(左)和量子比特(右)图示. 量子比特可以代表|0$\rangle $态和|1$\rangle $态的叠加态

    Figure 1.  Classic bit (left) and qubit (right). Qubit presents the superposition of |0$\rangle $ and |1$\rangle $.

    图 2  约瑟夫森结示意图.

    Figure 2.  The schematic of Josephson Junction.

    图 3  (a) 量子中继协议中的纠缠连接示意图[86]; (b) 量子中继模块之间的纠缠连接的实验系统示意图[86]

    Figure 3.  (a) A sketch of entanglement connection (swapping) in the quantum repeater protocol[86]; (b) the whole experimental set-up[86]

    图 4  多光子玻色采样实验装置图[97]

    Figure 4.  Experimental set-up for multiphoton boson-sampling[97].

    图 5  (a), (b), (c)展示了在x方向为有限边界而y方向为周期性边界时的能级结构, 从(a)到(c)缓慢增加磁场h的大小, 当满足$ {\psi }_{s}^{2}+ϵ{\left(\mathrm{0, 0}\right)}^{2} < {h}^{2} < {\psi }_{s}^{2}+ϵ{\left(0, \mathrm{\pi }\right)}^{2} $时, 即(c), 边界涌现了两个无能隙的边界模, 表明发生了拓扑相变[114]

    Figure 5.  (a), (b), and (c) The band energy of the lattice Hamiltonian with edges at x direction. The magnetic field increases from Figure (a) to Figure (c). The red thin line indicates a gapless chiral edge mode localized on the one side and green thick line a gapless chiral edge mode on the other side. They appear for$ {\psi }_{s}^{2}+ϵ{\left(\mathrm{0, 0}\right)}^{2} < {h}^{2} < {\psi }_{s}^{2}+ϵ{\left(0, \mathrm{\pi }\right)}^{2} $ at Figure (c), which indicates the occurrence of topological phase transition[114].

    图 6  三维拓扑超导体测量量子热霍尔效应的实验示意图[127]

    Figure 6.  Illustration of the experimental setting for the measurement of quantum thermal Hall effect in the 3D topological superconductor[127].

    图 7  (a) 纳米线在普通金属/超导体结 (NS) 上示意图[134]; (b) 纳米线在超导体/普通金属/超导体约瑟夫森结 (SNS) 上示意图[134]

    Figure 7.  Schematic pictures of NS (a) and SNS (b) junctions[134]

    图 8  微分电导GNS随偏置电压eV的变化曲线 (a) 不具有拓扑性的纳米线的曲线[134]; (b) 具有拓扑性的纳米线的曲线[134]

    Figure 8.  The differential conductance of NS nanowires is plotted as a function of the bias voltage for nontopological nanowire in (a) and for the topological nanowire in (b)[134].

    图 9  拓扑纳米线的SNS结的电流-相位关系, 作为对比, 黑色实线是非拓扑纳米线的电流-相位关系[134]

    Figure 9.  Current-phase relationship in SNS junctions of topological wire. For comparison, the results for nontopological wire is plotted with a solid line[134].

    图 10  在CuxBi2Se3中发现了Tc = 3.8 K的超导电性[135]

    Figure 10.  Superconductivity at 3.8 K in CuxBi2Se3[135].

    图 11  Fe1+ySexTe1–x上马约拉纳零能模的近量子化电导平台特征 (a) 扫描隧道显微镜示意图[148]; (b) 小图中涡旋的线界面图[148]; (c) 微分电导谱[148]; (d) 三维微分电导谱[148]; (e) 图(c)的彩色图[148]; (f), 图(e)在零偏置是的水平切线[148]; (g) 图(e)在高偏置是的水平切线[148]

    Figure 11.  Zero-bias conductance plateau observed on Fe1+ySexTe1–x: (a) Schematic of variable tunnel coupling STM/S method[148]; (b) a line-cut intensity plot along the dashed white arrow in the inset[148]; (c) an overlapping plot of dI/dV spectra[148]; (d) 3D plot of tunnel coupling dependent measurement, dI/dV (E, GN) [148]; (e) color-scale plot of Figure (c) [148]; (f) horizontal line-cut at the zero-bias from Figure (e)[148]; (g) horizaontal line-cuts at high-bias from Figure (e)[148].

    图 12  超导抗磁性在Fe1+ySexTe1–x薄片中的分布 (a) 样品光学显微镜照片[150]; (b), (c) 样品的抗磁和磁化强度sSQUID扫描图[150]; (d)—(g) 随温度变化的抗磁sSQUID扫描图[150]; (h) 图(d)中r箭头指向的不同温度抗磁曲线[150]; (i) 根据图(h)做出的彩图[150]; (j) 在图(d)中1和2两点处提取的随温度变化的超流密度[150]

    Figure 12.  Distinctive edge features in susceptometry of Fe1+ySexTe1–x flake: (a) Optical image of the sample[150]; (b), (c) the susceptometry and magnetometry images of the sample, respectively[150]; (d)–(g) susceptometry images of the sample at various T[150]; (h) line cuts of the susceptometry images at various T along the vector direction (r) as labeled by the arrow in Figure (d) [150]; (i) interpolated image from the line cuts in Figure (h) [150]; (j) superfluid densities as a function of T extracted from point 1 and 2 in Figure (d)[151]

    图 13  Li(Fe, Co)As的电子结构 (a) Li(Fe, Co)As的晶体结构[151]; (b) LiFeAs随ΓMΓZ的能带色散[151]; (c), (b) Cut D处的面内能带结构[151]; (d) LiFeAs (001)面的表面谱[151]; (e) 15 K时LiFe1–xCoxAs (x = 3%)的ARPES谱[151]; (f) 10 K时LiFe1–xCoxAs (x = 9%)的ARPES谱[151]

    Figure 13.  Electronic structure of Li(Fe, Co)As: (a) Crystal structure of Li(Fe, Co)As[151]; (b) zoomed-in view of the LiFeAs band dispersion along ΓM and ΓZ[151]; (c) in-plane band structure at Cut D in Figure(b) [151]; (d) (001) surface spectrum of LiFeAs[151]; (e) ARPES intensity plot of LiFe1–xCoxAs (x = 3%) at 15  K[151]; (f) ARPES intensity plot of LiFe1–xCoxAs (x = 9%) at 10  K[151].

    图 14  (Li, Fe)OHFeSe中量子化的零偏置电导峰[153]

    Figure 14.  Quantized zero-bias conductance peak in (Li, Fe) OHFeSe[153].

    图 15  Sn1–xInxTe的零偏置电导峰 (a) 固定磁场改变温度[156]; (b) 固定温度改变磁场[156]

    Figure 15.  Zero-bias conductance peak in Sn1–xInxTe: (a) Different temperatures at B = 0 T[156]; (b) different magnetic fields at T = 0.37 K[156].

    图 16  TaSe3的电子结构[159]

    Figure 16.  Electronic structure of TaSe3[159].

    图 17  2M-WS2的拓扑表面态 [161]

    Figure 17.  Topological surface states of 2M-WS2[161].

    图 18  PbTaSe2中有两个拓扑表面态[165]

    Figure 18.  Two topological surface states in PbTaSe2[165].

    图 19  分子束外延β-Bi2Pd薄膜的拓扑超导电性和马约拉纳零能模 (a) 扫描隧道显微镜的扫描图[169]; (b) β-Bi2Pd 的微分电导谱[169]; (c) 归一化的零偏置电导峰分布图[169]; (d) 隧穿电导谱[169]; (e) 涡旋核心附近的归一化微分电导谱[169]

    Figure 19.  Topological superconductivity and MZM in β-Bi2Pd film grown by MBE: (a) STM topography[169]; (b) Differential conductance dI/dV spectrum[169]; (c) normalized zero-bias conductance map[169]; (d) tunneling conductance dI/dV spectrum[169]; (e) normalized dI/dV spectra measured at location with radial distance r from the vortex center[169].

    图 20  单个晶胞厚的WTe2通过门电压调控出超导电性[174]

    Figure 20.  Gate-tuned superconductivity in monolayer WTe2[174]

    图 21  Bi2Te3/NbSe2上的零偏置电导峰劈裂 (a) 电导曲线[181]; (b) 通过图(a)做出的彩色图[181]; (c)—(g) 2—6层的电导彩色图[181]; (h) 劈裂点随层数变化曲线[181]

    Figure 21.  (a) A series of dI/dV curves[181]; (b) the color image of Figure (a) [181]; (c)–(g) the experimental results for 2-6QL samples, following the similar data process of Figure (b) [181]; (h) summary of the start points of the peak split [181].

    图 22  分子束外延生长的Al/InAs结构中测得的量子化零偏置电导峰 (a) B-Vsd扫描谱[187]; (b) 从图(a)中提取的不同磁场下的微分电导曲线[187]

    Figure 22.  Quantum zero-bias conductance peak in Al/InAs grown by MBE: (a) B-Vsd sweep[187]; (b) differential conductance line-cut plots taken from Figure (a) at various B values[187].

    图 23  不同磁场下隧穿电导峰[190]

    Figure 23.  The differential conductance curves as a function of the bias voltage at different magnetic fields[190].

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Metrics
  • Abstract views:  10609
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Publishing process
  • Received Date:  31 March 2022
  • Accepted Date:  26 April 2022
  • Available Online:  07 August 2022
  • Published Online:  20 August 2022

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