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Preparation, structures and properties of tungsten-containing refractory high entropy alloys

Huang Wen-Jun Qiao Jun-Wei Chen Shun-Hua Wang Xue-Jiao Wu Yu-Cheng

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Preparation, structures and properties of tungsten-containing refractory high entropy alloys

Huang Wen-Jun, Qiao Jun-Wei, Chen Shun-Hua, Wang Xue-Jiao, Wu Yu-Cheng
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  • As a new type of multi-principal component solid solution alloy, high-entropy alloy has the four major effects, i.e. high entropy, lattice distortion, slow diffusion, and “cocktail” in orderly arrangement of atoms and chemical disorder. It exhibits excellent comprehensive performances and is expected to be used as a new type of high-temperature structural material, wear-resistant material, and radiation-resistant material, which is used in the areas of aerospace, mining machinery, nuclear fusion reactors and others. In this paper, the present research status, conventional preparation methods, microstructures and phase compositions of tungsten high entropy alloys are mainly introduced. In view of the excellent comprehensive properties of high-entropy alloys, the mechanical properties, friction and wear resistance, and radiation resistance of tungsten high-entropy alloys are summarized, and the future research directions of tungsten high-entropy alloys are also prospected.
      Corresponding author: Wu Yu-Cheng, ycwu@hfut.edu.cn
    • Funds: Project supported by the National Key Research and Development Program of China (Grant Nos. 2014GB121000, 2019YFE03120002) and the National Natural Science Foundation of China (Grant Nos. 514740830, 52020105014, 51828101)
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  • 图 1  强度与温度的关系[41]

    Figure 1.  The relationship between strength and temperature[41].

    图 2  NbMoTaWHEAs薄膜的制备与表征[56]

    Figure 2.  Fabrication and characterization of NbMoTaW HEA films[56].

    图 3  增材制造示意图[59]

    Figure 3.  Schematic illustration of additive manufacturing[59].

    图 4  NbMoTaW和VNbMoTaW的SEM背散射图像[39]

    Figure 4.  SEM backscatter electron images of a polished coss-section of NbMoTaW and VNbMoTaW[39].

    图 5  室温工程应力应变曲线[40,51]

    Figure 5.  Compressive engineering stress-strain curves at room temperature[40,51].

    图 6  CuMoTaWV难熔HEAs纳米柱及其工程应力应变曲线[53]

    Figure 6.  Nanopillar of CuMoTaWV: (a, b) before and (c) after the compression test, and (d) stress-strain plot from nanocompression[53].

    图 7  合金屈服强度与温度的关系[40]

    Figure 7.  The temperature dependence of the yield stress of Nb25Mo25Ta25W25 and V20Nb20Mo20Ta20W20 HEAs and two superalloys, Inconel 718 and Haynes 230[40].

    图 8  不同的工艺参数和基底制备MoFeCrTiWAlNbHEAs涂层的结果[58]

    Figure 8.  Wear volume loss of HEA coatings fabricated by laser cladding with various processing parameters and substrate after sliding time for 15 min[58].

    图 9  相应图表的结构以及两种合金在每个滑动距离和所使用的计数器体的磨损率值 (a) 滑动距离400 m; (b) 滑动距离1000 m; (c) 滑动距离2000 m [99]

    Figure 9.  Comparative diagrams of the volume loss (left) and the wear rate (right) of Mo20Ta20W20Nb20V20 versus Inconel 718, tested with both an alumina and a steel ball for sliding distances of (a) 400 m, (b) 1000 m, and (c) 2000 m, respectively[99].

    图 10  在1073 K下1–MeV Kr+2原位辐照HEAs的TEM明场显微图[55]

    Figure 10.  Bright-field TEM micrographs as a function of dpa of in situ 1–MeV Kr+2-irradiated HEA at 1073 K using a dpa rate of 0.0016 dpa/s: (A) Pre-irradiation; (B) 0.2 dpa; (C) 0.6 dpa; (D) 1.0 dpa; (E) 1.6 dpa; (F) 3.2 dpa; (G) 4.8 dpa; (H) 6.4 dpa; (I) 8 dpa[55].

    图 11  合金准静态与动态下的真实应力应变曲线和在高速冲击下的侵彻性能[76]

    Figure 11.  The true compressive stress-strain curve of the alloy under quasi-static and dynamic conditions and its penetration performance under high-speed impact[76].

    图 12  (CrNbTaTiW)C薄膜和不锈钢参考材料的动电位极化曲线[80]

    Figure 12.  Potential polarization curve of (CrNbTaTiW)C film and stainless steel[80].

    表 1  近年来一些典型钨HEAs的相组成

    Table 1.  Phase composition of some typical Tungsten high entropy alloys in recent years.

    年份合金条件文献
    2010NbMoTaWACBCC[39]
    2010VNbMoTaWACBCC[39]
    2012Ti-Nb-Ta-WMSBCC[60]
    2015CrFeNiV0.5W0.25ACFCC+$ \sigma $[61]
    2015CrFeNiV0.5W0.5ACBCC+FCC+$ \sigma $[61]
    2015CrFeNiV0.5W0.75ACBCC+FCC+$ \sigma $[61]
    2015CrFeNiV0.5WACBCC+FCC+$ \sigma $[61]
    2015CrFeNi2V0.5W0.25ACFCC+$ \sigma $[61]
    2015CrFeNi2V0.5W0.5ACFCC+$ \sigma $[61]
    2015CrFeNi2V0.5W0.75ACBCC+FCC+$ \sigma $[61]
    2015CrFeNi2V0.5WACBCC+FCC+$ \sigma $[61]
    2015Cr0.5VNbMoTaWACBCC[62]
    2015CrVNbMoTaWACBCC[62]
    2015Cr2VNbMoTaWACBCC[62]
    2016VZrMoTaWAC(+A)BCC+ BCC+HCP+Laves[63]
    2016VNbTaWACBCC[64]
    2016TiVNbTaWACBCC[64]
    2017TiNbMoTaWACBCC[65]
    2017TiVNbMoTaWACBCC[65]
    2017TixNbMoTaW (x = 0–1)ACBCC[66]
    2017TiVCrTaWxMA+SPSBCC[67]
    2018VCrMoTaWMABCC[68]
    2018V11Cr15Ta36W38MSBCC[55]
    2018AlTiCrFeNbMoWLCBCC+IM[58]
    2018Ti8Nb23Mo23Ta23W23MA+SPSBCC+Carbide[51]
    2018VCrFeTaxWx (x = 0.1, 0.2)ACBCC[69]
    2018VCrFeTaxWx (x = 0.3)ACBCC1+BCC2[69]
    2018VCrFeTaxWx (x = 0.4, 1)ACBCC1+BCC2+Laves[69]
    2018VNbMoTaWMA+HPHTBCC[50]
    2019VCuMoTaWMABCC[49,53]
    2019V26.4Cr31.3Mo23.6W18.7ACBCC[70]
    2019TiNiNbTaWACBCC+$ \mu $[71]
    2019Al10Ti18Ni18Nb18Ta18W18ACBCC+$ \mu $+L21[71]
    2019VCrNbMoTaWMA+SPSBCC+Laves[48]
    2019Ti34.4Nb32.9Mo17W15.7ACBCC[72]
    2019Mo-Ru-Rh­W-IrACBCC+HCP+FCC[73,74]
    2019AlTiCrFe1.5NbxMoW (x = 1.5–3)LCBCC+MC+Laves[75]
    2019TiCrNbMoWMA+SPSBCC+Laves[47]
    2020FeNiMoWACFCC+BCC+$ \mu $[76]
    2020V2.5Cr1.2Co0.04MoWACBCC[77]
    2020NbMoReTaWTaAC+ABCC[44]
    2020(TiNbMoW)100–xCrx (x = 5–20)MA+SPSBCC+Laves[43]
    2020(VNbMoTaW)99B1MA+HPHTBCC[78]
    AC = 铸造, MS = 磁控溅射, A = 热处理, MA = 球磨, SPS = 放电等离子烧结, LC = 激光熔覆, HPHT = 高压/高压固结技术
    DownLoad: CSV
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Publishing process
  • Received Date:  25 November 2020
  • Accepted Date:  21 December 2020
  • Available Online:  12 May 2021
  • Published Online:  20 May 2021

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