基于B4C和Cu材料具有明显电阻率及熔点差的特点,提出了在超高压下通电快速烧结B4C/Cu梯度复合材料的新工艺.在 2~4GPa、12kW,40s及适当的热处理条件下成功制备出了成分分布从0~100%的接近理论密度的B4C/Cu层状复合材料;显微观察显示材料的成分和结构是呈梯度分布的.化学溅射实验表明其产额比 SMF 800核纯级石墨降低 70%;在Tokamak原位等离子体辐照下,材料表面无明显损伤.
Based on their distinct resistivity and melting point, a new approach for fabricating graded B4C/Cu composite by rapid self-resistance sintering under ultra-high
pressure was proposed in this paper and with which a near dense plasma facing material with 0-100% compositional distributions of B4C was obtained
on conditions of 12kW electric power input, 2-4GPa pressure applied, 40s duration and properly consecutive heat treatment. Well-graded composition and
structure of that composite were demonstrated by SEM analysis. Tests on plasma relevant performances show that the chemical sputtering yield of B4C/Cu graded
composite is 70% lower than that of SMF 800 nuclear graphite, and the surface of the composite is almost no damages after in-situ plasma irradiation in Tokamak apparatus.
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