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是具有手性的无质量费米子, 是其本身的反粒子, 只能存在于1+1维(即1维空间+1维时间)或者9+1维. 在凝聚态物理中, 1维可看成1/2分数化的狄拉克费米子, 并作为二维拓扑态的边缘元激发. 奇数个边缘态的存在也预示着体系中存在满足非阿贝尔量子统计的伊辛任意子. 也可进行非阿贝尔编织, 理论上可用来实现容错量子计算, 因此近年来在凝聚态物理研究中引起了广泛的兴趣. 本文从二维拓扑态出发, 介绍手征拓扑超导态和量子反常霍尔态之间的深刻联系, 并由此得出量子反常霍尔平台转变与超导近邻实现的方案, 最后以单通道为例, 探讨其实现电子态的非阿贝尓量子门.The chiral Majorana fermion, is a massless fermionic particle being its own antiparticle, which was predicted to live in (1+1)D (i.e. one-dimensional space plus one-dimensional time) or (9+1)D. In condensed matter physics, one-dimensional (1D) chiral Majorana fermion can be viewed as the 1/2 of the chiral Dirac fermion, which could arise as the quasiparticle edge state of a two-dimensional (2D) topological state of matter. The appearance of an odd number of 1D chiral Majorana fermions on the edge implies that there exist the non-Abelian defects in the bulk. The chiral Majorana fermion edge state can be used to realize the non-Abelian quantum gate operations on electron states. Starting with the topological states in 2D, we illustrate the general and intimate relation between chiral topological superconductor and quantum anomalous Hall insulator, which leads to the theoretical prediction of the chiral Majorana fermion from the quantum anomalous Hall plateau transition in proximity to a conventional s-wave superconductor. We show that the propagation of chiral Majorana fermions leads to the same unitary transformation as that in the braiding of Majorana zero modes, and may be used for the topological quantum computation.
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Keywords:
- chiral Majorana fermion/
- topological superconductor/
- quantum anomsloua Hall/
- non-abelian braiding
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图 2 (a) 基本想法: 将量子反常霍尔的手征狄拉克费米子一分为二得到; (b) 实现的量子反常霍尔绝缘体-超导体的异质结器件. 取自文献[41]
图 3 实现电子态的非阿贝尔量子门操作 (a) 量子反常霍尔绝缘体-手征拓扑超导-量子反常霍尔绝缘体的异质结器件实现电子态的非阿贝尔量子门, 其等价于实现单比特ZH量子门. 其中Z是泡利-Z门,H是Hadamard门; (b) Corbino异质结器件测量量子相干. 取自文献[38]
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