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Applications and progress of slow positron beam technique in the study of metal/alloy microdefects

Hu Yuan-Chao Cao Xing-Zhong Li Yu-Xiao Zhang Peng Jin Shuo-Xue Lu Er-Yang Yu Run-Sheng Wei Long Wang Bao-Yi

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Applications and progress of slow positron beam technique in the study of metal/alloy microdefects

Hu Yuan-Chao, Cao Xing-Zhong, Li Yu-Xiao, Zhang Peng, Jin Shuo-Xue, Lu Er-Yang, Yu Run-Sheng, Wei Long, Wang Bao-Yi
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  • In recent decades, the positron annihilation spectroscopy technique has been used to characterize the microdefects of materials due to its advantages of non-destruction and high sensitivity on an atomic level. Positron annihilation spectroscopy technique is widely used in the microstructure study of thin film material surface and interface due to the rapid development of the slow positron beam technology. The slow positron beam technique can provide depth distribution information about material surface microstructure. Therefore, it is widely used to study the distributed defect concentrations in crystalline materials and the properties of thin films, surfaces and interfaces of layered materials. This article summarizes the slow positron beam technique applications and progress in the study of metal alloy materials. Firstly, this article introduces the slow positron beam technology development and application research achievement in detail. Secondly, it provides how to acquire the slow positron beam, introduces some kinds of and the principles of experimental measurements, and the major methods include Doppler bradening spectroscopy, coincidence Doppler broadening and PL. Thirdly, according to the defects induced by different ways, the latest experimental results about the material internal microdefect formation mechanism, evolution mechanism, defect feature research, such as microstructure, chemical environment, electron density and momentum distribution are introduced. The methods of inducing defects mainly include irradiation, physical deformation and chemical corrosion. Particles irradiation can be classified as four parts according to the different types of particles. In addition, monolayer and multilayer thin films have also been summarized. Finally, the new technique of thermal desorption spectroscopy and experimental measurements of age-momentum correlation are proposed. We can know that positron annihilation spectroscopy technology is a very special and effective nuclear spectroscopy analysis method in material microstructure study, and the slow positron beam technique makes it possible to study the depth distribution information about the thin film material surface microstructure. There is no doubt that this technique will play a huge role in the progress of material science and the creation of industrial material.
      Corresponding author: Cao Xing-Zhong, caoxzh@ihep.ac.cn
    • Funds: Project supported by the National Natural Science Foundation of China (Grant Nos. 19927001, 19805010, 10835006, 10275076, 91226103, 91026006, 11475193).
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Publishing process
  • Received Date:  26 August 2015
  • Accepted Date:  29 September 2015
  • Published Online:  05 December 2015

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