[1] Ren C, Fang Z Z, Koopman M et al. Methods for improving ductility of tungsten: a review[J]. International Journal of Refractory Metals and Hard Materials, 75, 170-183(2018).
[2] Oh Y, Kwak N, Lee K et al. Ductility enhancement of tungsten after plastic deformation[J]. Journal of Alloys and Compounds, 787, 801-814(2019).
[3] Šestan A, Jenuš P, Krmpotič S N et al. The role of tungsten phases formation during tungsten metal powder consolidation by FAST: implications for high-temperature applications[J]. Materials Characterization, 138, 308-314(2018).
[4] Şahin Y. Recent progress in processing of tungsten heavy alloys[J]. Journal of Powder Technology, 2014, 1-22(2014).
[5] He H R, Liu Q, Bo X W et al. Preparation and application of tungsten-rhenium alloy[J]. Smelting Sensor Column, 25, 24-27(2015).
[6] Jaffee R I, Sims C T. The effect of rhenium on the fabricability and ductility of molybdenum and tungsten[R](1958).
[7] Yin X S[M]. W-Re alloy and W-Re thermocouple(1992).
[8] Gu D D, Zhang H M, Chen H Y et al. Laser additive manufacturing of high-performance metallic aerospace components[J]. Chinese Journal of Lasers, 47, 0500002(2020).
[9] Deprez K, Vandenberghe S, van Audenhaege K et al. Rapid additive manufacturing of MR compatible multipinhole collimators with selective laser melting of tungsten powder[J]. Medical Physics, 40, 012501(2013).
[10] Zhou X, Liu X H, Zhang D D et al. Balling phenomena in selective laser melted tungsten[J]. Journal of Materials Processing Technology, 222, 33-42(2015).
[11] Tan C L, Zhou K S, Ma W Y et al. Selective laser melting of high-performance pure tungsten: parameter design, densification behavior and mechanical properties[J]. Science and Technology of Advanced Materials, 19, 370-380(2018).
[12] Zhang D Q, Cai Q Z, Liu J H et al. Microstructural evolvement and formation of selective laser melting W-Ni-Cu composite powder[J]. The International Journal of Advanced Manufacturing Technology, 67, 2233-2242(2013).
[13] Zhang D Q. Research on microstructure evolution of tungsten and tungsten alloys in selective laser melting process[D](2011).
[14] Wang M B, Li R D, Yuan T C et al. Selective laser melting of W-Ni-Cu composite powder: densification, microstructure evolution and nano-crystalline formation[J]. International Journal of Refractory Metals and Hard Materials, 70, 9-18(2018).
[15] Wang X C. Microstructure and properties of selective laser melting AlSi10Mg alloy[D](2017).
[16] An L. Effect of rhenium addition on microstructure and properties of molybdenum alloys[D](2011).
[17] Bian P Y, Yin E H. Effect of laser power on morphology and residual stress of molten pool in selective laser melting of metals[J]. Laser & Optoeletronics Progress, 57, 011403(2020).
[18] Yuan G C. Effect of processes on microstructure and properties of AlSi10Mg alloy produced by selective laser melting[D](2019).
[19] Ng G K L, Jarfors A E W, Bi G et al. Porosity formation and gas bubble retention in laser metal deposition[J]. Applied Physics A, 97, 641-649(2009).
[20] Vrancken B, King W E, Matthews M J. In-situ characterization of tungsten microcracking in Selective Laser Melting[J]. Procedia CIRP, 74, 107-110(2018).
[21] Raffo P L, Klopp W D[M]. Refractory metals and alloys IV: research and development(1969).
[22] Klopp W D, Raffo P L, Witzke W R. Strengthening of molybdenum and tungsten alloys with HfC[J]. The Journal of The Minerals, Metals & Materials Society, 23, 27-38(1971).
[23] Zheng Y L, He Y L, Chen X H et al. Elevated-temperature tensile properties and fracture behavior of GH3536 alloy formed via selective laser melting[J]. Chinese Journal of Lasers, 47, 0802008(2020).