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Research progress of metal-insulator phase transition in VO2 induced by electric field

Sun Xiao-Ning Qu Zhao-Ming Wang Qing-Guo Yuan Yang Liu Shang-He

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Research progress of metal-insulator phase transition in VO2 induced by electric field

Sun Xiao-Ning, Qu Zhao-Ming, Wang Qing-Guo, Yuan Yang, Liu Shang-He
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  • Vanadium dioxide (VO2) is a typical representative of strongly correlated electronic systems, which undergoes a reversible transition from the insulator phase to metal phase, induced by a certain threshold for each of temperature, electric field, illumination and pressure. The crystal structure of VO2 will undergo a reversible transition from monoclinic structure to tetragonal rutile structure when the phase transition happens, which is considered as the microscopic mechanism of VO2 metal-insulator transition (MIT). The conductivity of VO2 can be increased by 2—5 orders of magnitude when the MIT is induced by electric field, which makes VO2 possess good application prospects in the fields of restructurable slot antenna, terahertz radiation, intelligent electromagnetic protection materials, etc. Therefore, the reversible metal-insulator phase transition in VO2, induced by electric field, has long been a research hotspot, which however, has been seldom reported. Firstly, in this paper, the changes of the crystal structure and energy band structure of VO2 during MIT are introduced briefly. The methods of regulating the phase transition are given, including temperature control, bandwidth and band-filling control. Then, the important discovery and research progress of VO2 MIT induced by electric field based on the research method, response time, critical threshold field and phase transition mechanism are summarized and reviewed comprehensively. The method of studying the VO2 phase transition relates to its structure, including planar structure, three-terminal gated ?eld effect switch and sandwiched layer structure. The sandwich layer structure is more suitable for investigating the MIT characteristics of VO2 in experimental stage because of its structural advantage of preparation and test. The response time of VO2 MIT can be completed in nanoseconds, of which the substantial parameter has been revealed by many reports, also including the excellent reversibility of VO2 MIT. The MIT critical threshold field of the VO2 film can be tuned by element doping, coexistence of multivalent vanadium oxides and multiple physical field synergism effectively. The MIT mechanism of VO2 induced by electric field has been proposed so far, which includes joule heating mechanism and pure electric field mechanism, and the latter is considered to be more likely to give a reasonable explanation. Finally, in the paper the current problems of the VO2 MIT research and the near-future development direction of the VO2 MIT materials are also pointed out.
      Corresponding author: Qu Zhao-Ming, iamqzm3990@163.com ; Liu Shang-He, liushh@cae.cn
    • Funds: Project supported by the Foundation of National Key Laboratory on Electromagnetic Environment Effects, China (Grant No. 614220504030617).
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  • 图 1  VO2晶体结构图[32] (a) M相; (b) R相

    Figure 1.  Crystal structure of VO2: (a) M phase; (b) R phase.

    图 2  电场作用下VO2薄膜中的电流变化曲线[8]

    Figure 2.  Changes of currents by application ofthe electric field to VO2 thin films[8].

    图 3  VO2器件结构示意图 (a)平面结构[36]; (b)三端场效应管结构[7]; (c)三明治结构[45]

    Figure 3.  Diagram of VO2 device structure: (a) Planar structure[36]; (b) three-terminal gated field effect switches[7]; (c) layered structure[45].

    图 4  量子阱结构示意图(内嵌图为量子阱结构的电容器件模型[46]

    Figure 4.  Schematic of quantum well structure (inset shows a capacitance device model for the quantum well structure)[46].

    图 5  短脉冲响应曲线[36]

    Figure 5.  Response curve of short pulse[36].

    图 6  (a) Sawyer-Tower测试电路; (b)方波脉冲电压与峰值电流关系图(内嵌图为加载7 V和10 V开关电压时的电压和电流曲线)[47]

    Figure 6.  (a) Sawyer-Tower test circuit; (b) peak current as a function of square wave pulse voltage (the inset illustrates voltage and current curves using applied switching pulses of 7 V and 10 V)[47].

    图 7  VO2薄膜温度调控相变电场曲线图(电极间距5 mm)[60]

    Figure 7.  MIT electric field curve controlled by temperature for VO2 thin film (the electrode spacing is 5 mm) [60].

    图 8  电场强度调控相变温度的关系图[60]

    Figure 8.  MIT temperature curve controlled by electric field intensity[60].

    图 9  (a) VO2纳米纤维; (b)测试器件; (c)温度响应曲线[64]

    Figure 9.  (a) VO2 nanofibers; (b) test device; (c) curve of temperature response.[64]

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Metrics
  • Abstract views:  14357
  • PDF Downloads:  499
  • Cited By: 0
Publishing process
  • Received Date:  24 January 2019
  • Accepted Date:  14 March 2019
  • Available Online:  01 May 2019
  • Published Online:  20 May 2019

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