X. N. Li scite author profile

Electric transport coefficients such as carrier type, density, and mobility are the important physical parameters in designing functional devices. In this work, we report the study on the electric transport coefficients of the highly epitaxial LaBaCo2O5 + δ (LBCO) films, which were discussed as a function of electric conductivity for the first time and compared with the results calculated by the theory for mixed conduction. The mobility in the LBCO films was determined to be ∼0.85 and ∼40 cm2/V s for holes and electrons, respectively, and the density of p-type carriers strongly depends on the oxygen deficiency. Solid evidence is presented to demonstrate that the oxygen deficiency cannot make LBCO materials changed from p- to n-type. The n-type conduction observed in experiment is a counterfeit phenomenon caused by the deficiency in Hall measurement, rather than a realistic transition induced by oxygen deficiency. In addition, the temperature-dependent conductivity was discussed using the differential coefficients, which might be useful in the study of the samples with magnetic transition.

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Effects of adding elements M (M = C, B, Mn, Al and Al + Co) on stability of amorphous semiconducting Fe–Si films

Zheng

Liu

et al. 2018

J Mater Sci: Mater Electron

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Surface Modification of Light Alloys by Low-Energy High-Current Pulsed Electron Beam

Zhang

Hao

Grosdidier

et al. 2012

Journal of Metallurgy

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This paper reviews results obtained by the research groups developing the low-energy high-current pulsed electron beam (LEHCPEB) in Dalian (China) and Metz (France) on the surface treatment of light alloys. The pulsed electron irradiation induces an ultra-fast thermal cycle at the surface combined with the formation of thermal stress and shock waves. As illustrated for Mg alloys and Ti, this results in deep subsurface hardening (over several 100 μm) which improves the wear resistance. The analysis of the top surface melted surface of light alloys also often witnesses evaporation and condensation of chemical species. This phenomenon can significantly modify the melt chemistry and was also suggested to lead to the development of specific solidification textures in the rapidly solidified layer. The potential use of the LEHCPEB technique for producing thermomechanical treatments under the so-called heating mode and, thus, modify the surface crystallographic texture, and enhance solid-state diffusion is also demonstrated in the case of the FeAl intermetallic compound.

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ChemInform Abstract: Surface Modification of Light Alloys by Low‐energy High‐current Pulsed Electron Beam

et al. 2013

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X. N. Li

Barrierless Cu-Ni-Mo Interconnect Films with High Thermal Stability Against Silicide Formation

Electric transport coefficients in highly epitaxial LaBaCo2O5 + δ films with “p-to-n” transition induced by oxygen deficiency

Effects of adding elements M (M = C, B, Mn, Al and Al + Co) on stability of amorphous semiconducting Fe–Si films

Surface Modification of Light Alloys by Low-Energy High-Current Pulsed Electron Beam

ChemInform Abstract: Surface Modification of Light Alloys by Low‐energy High‐current Pulsed Electron Beam

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