Tian Wenchao, Yu Wenbo, Shi Jing, Wang Yongkun
School of Electro-Mechanical Engineering, Xidian University, Number 2 Taibai South Road, Xi'an 710071, China.
Materials (Basel). 2017 Jul 17;10(7):814. doi: 10.3390/ma10070814.
Topological insulator (TI), a promising quantum and semiconductor material, has gapless surface state and narrow bulk band gap. Firstly, the properties, classifications and compounds of TI are introduced. Secondly, the preparation and doping of TI are assessed. Some results are listed. (1) Although various preparation methods are used to improve the crystal quality of the TI, it cannot reach the industrialization. Fermi level regulation still faces challenges; (2) The carrier type and lattice of TI are affected by non-magnetic impurities. The most promising property is the superconductivity at low temperature; (3) Magnetic impurities can destroy the time-reversal symmetry of the TI surface, which opens the band gap on the TI surface resulting in some novel physical effects such as quantum anomalous Hall effect (QAHE). Thirdly, this paper summarizes various applications of TI including photodetector, magnetic device, field-effect transistor (FET), laser, and so on. Furthermore, many of their parameters are compared based on TI and some common materials. It is found that TI-based devices exhibit excellent performance, but some parameters such as signal to noise ratio (S/N) are still lower than other materials. Finally, its advantages, challenges and future prospects are discussed. Overall, this paper provides an opportunity to improve crystal quality, doping regulation and application of TI.
拓扑绝缘体(TI)是一种很有前景的量子和半导体材料,具有无隙表面态和狭窄的体带隙。首先,介绍了TI的性质、分类和化合物。其次,评估了TI的制备和掺杂情况,并列出了一些结果。(1)尽管使用了各种制备方法来提高TI的晶体质量,但仍无法实现工业化。费米能级调控仍面临挑战;(2)TI的载流子类型和晶格受非磁性杂质影响。最有前景的特性是低温超导性;(3)磁性杂质会破坏TI表面的时间反演对称性,这会在TI表面打开带隙,从而产生一些新颖的物理效应,如量子反常霍尔效应(QAHE)。第三,本文总结了TI的各种应用,包括光电探测器、磁性器件、场效应晶体管(FET)、激光器等。此外,基于TI和一些常见材料对它们的许多参数进行了比较。发现基于TI的器件表现出优异的性能,但一些参数,如信噪比(S/N)仍低于其他材料。最后,讨论了其优点、挑战和未来前景。总体而言,本文为提高TI的晶体质量、掺杂调控和应用提供了契机。
