In this study, the mechanical properties of tungsten-rhenium wires with nanofibrous microstructure were investigated at both room temperature(RT) and 800?C. The strengthening mechanism associated to the nanofibrous mi...In this study, the mechanical properties of tungsten-rhenium wires with nanofibrous microstructure were investigated at both room temperature(RT) and 800?C. The strengthening mechanism associated to the nanofibrous microstructure was discussed. The results showed that the tungsten-rhenium wires with nanofibrous grains exhibited a very high tensile strength reaching values of 3.5 GPa and 4.4 GPa for the coarse(grains diameter of 240 nm) and fine(grains diameter of 80 nm) wires, respectively. With increasing the temperature from RT to 800?C, the tensile strength decreased slightly but still held high values(1.8 GPa and 3.8 GPa). All the fracture surfaces exhibited apparent necking and characteristics of spear-edge shaped fracture surface, indicating excellent ductility of the wires. A model of the strengthening mechanism of these tungsten-rhenium wires was proposed.展开更多
We have systemically investigated the synergistic evolution of rhenium(Re)and irradiation defects in tungsten(W)-Re alloys under different temperatures and irradiation doses using object Kinetic Monte Carlo method.Our...We have systemically investigated the synergistic evolution of rhenium(Re)and irradiation defects in tungsten(W)-Re alloys under different temperatures and irradiation doses using object Kinetic Monte Carlo method.Our results revealed the underlying mechanism for the transition of Re effect on W from beneficial to harmful during the Re-defects evolution with the increase of irradiation dose,in which tem-perature always plays a critical role.On the one hand,Re will significantly promote the defect annihila-tion at low irradiation doses and high temperatures,thereby effectively reducing their sizes and number densities.This is due to the formation of stable Re-SIAs complexes that can be eliminated by the mobile vacancy-type defects,whereas the transition of the migration pattern of SIAs only plays a weak role in the defect recombination in W-Re system.On the other hand,with the increase of irradiation dose,Re will aggregate to form Re-rich clusters or even precipitates.Interestingly,the formation mechanism of Re-rich clusters is also dependent on temperature.At low temperatures,the interstitial-mediated mech-anism plays a crucial role in the Re-rich cluster formation,while at high temperatures,both SIA-type and vacancy-type defects will act as the transport carriers of Re to promote their clustering.Accordingly,the critical conditions for the transition of Re from beneficial to harmful and the formation of Re-rich clusters at different tem peratures and irradiation doses are given with the help of the phase diagram.Our work presents the temperature dependence of the synergy of Re and irradiation defects in W-Re in fusion-relevant environment,which provides a good reference for the development of radiation-resistant materials and the prediction of W performance in fusion reactors.展开更多
铼在地壳中的丰度低且分散,多伴生于钨钼矿中,现有方法常采用碱熔富集,流程长且繁琐,亟需开发一种简便快捷的检测方法。本文建立了逆王水微波消解钨钼矿石样品,8-羟基喹啉沉淀分离钨钼元素,与电感耦合等离子体质谱联用的检测方法。结果...铼在地壳中的丰度低且分散,多伴生于钨钼矿中,现有方法常采用碱熔富集,流程长且繁琐,亟需开发一种简便快捷的检测方法。本文建立了逆王水微波消解钨钼矿石样品,8-羟基喹啉沉淀分离钨钼元素,与电感耦合等离子体质谱联用的检测方法。结果表明:0.0500g样品,2.80mL逆王水即可实现铼元素的全部溶出,0.20mL有机沉淀剂8-羟基喹啉(3%)在乙酸-乙酸铵缓冲体系(p H 4.5)中可选择性沉淀钼、钨元素,有效消除基体元素钼、钨(沉淀率>95%)对Re定量干扰,同时不引入新干扰元素。相比现有分离富集前处理流程更加简便快捷,前处理时间缩短为现有方法的1/4;该方法对Re的检出限为6.9ng/g,采用国家一级标准物质钼矿石(GBW07238)、钼矿石(GBW07285)、铼钼矿石(GBW07373)和钨锡铋矿石(GBW07369)对方法的准确度进行了验证,测定值与推荐值吻合,相对误差为0.71%~6.07%,RSD<5%。本方法建立的“消解-分离富集”处理流程所需时间从常规的8~12h缩短至2h左右,在准确定量矿石样品中Re的同时简化了样品前处理流程,快速的样品处理及低廉的测试成本有助于关键稀有金属矿产的开发利用。展开更多
基金financially supported by the National Natural Science Foundation of China(No.51271021)Beijing Natural Science Foundation(No.2162025)State Key Laboratory for Advanced Metals and Materials,University of Science and Technology Beijing
文摘In this study, the mechanical properties of tungsten-rhenium wires with nanofibrous microstructure were investigated at both room temperature(RT) and 800?C. The strengthening mechanism associated to the nanofibrous microstructure was discussed. The results showed that the tungsten-rhenium wires with nanofibrous grains exhibited a very high tensile strength reaching values of 3.5 GPa and 4.4 GPa for the coarse(grains diameter of 240 nm) and fine(grains diameter of 80 nm) wires, respectively. With increasing the temperature from RT to 800?C, the tensile strength decreased slightly but still held high values(1.8 GPa and 3.8 GPa). All the fracture surfaces exhibited apparent necking and characteristics of spear-edge shaped fracture surface, indicating excellent ductility of the wires. A model of the strengthening mechanism of these tungsten-rhenium wires was proposed.
基金This work is financially supported by the National Natu-ral Science Foundation of China(Nos.11905135,12075022 and 12192281)the National MCF Energy R&D Program(No.2018YFE0308103).
文摘We have systemically investigated the synergistic evolution of rhenium(Re)and irradiation defects in tungsten(W)-Re alloys under different temperatures and irradiation doses using object Kinetic Monte Carlo method.Our results revealed the underlying mechanism for the transition of Re effect on W from beneficial to harmful during the Re-defects evolution with the increase of irradiation dose,in which tem-perature always plays a critical role.On the one hand,Re will significantly promote the defect annihila-tion at low irradiation doses and high temperatures,thereby effectively reducing their sizes and number densities.This is due to the formation of stable Re-SIAs complexes that can be eliminated by the mobile vacancy-type defects,whereas the transition of the migration pattern of SIAs only plays a weak role in the defect recombination in W-Re system.On the other hand,with the increase of irradiation dose,Re will aggregate to form Re-rich clusters or even precipitates.Interestingly,the formation mechanism of Re-rich clusters is also dependent on temperature.At low temperatures,the interstitial-mediated mech-anism plays a crucial role in the Re-rich cluster formation,while at high temperatures,both SIA-type and vacancy-type defects will act as the transport carriers of Re to promote their clustering.Accordingly,the critical conditions for the transition of Re from beneficial to harmful and the formation of Re-rich clusters at different tem peratures and irradiation doses are given with the help of the phase diagram.Our work presents the temperature dependence of the synergy of Re and irradiation defects in W-Re in fusion-relevant environment,which provides a good reference for the development of radiation-resistant materials and the prediction of W performance in fusion reactors.
文摘铼在地壳中的丰度低且分散,多伴生于钨钼矿中,现有方法常采用碱熔富集,流程长且繁琐,亟需开发一种简便快捷的检测方法。本文建立了逆王水微波消解钨钼矿石样品,8-羟基喹啉沉淀分离钨钼元素,与电感耦合等离子体质谱联用的检测方法。结果表明:0.0500g样品,2.80mL逆王水即可实现铼元素的全部溶出,0.20mL有机沉淀剂8-羟基喹啉(3%)在乙酸-乙酸铵缓冲体系(p H 4.5)中可选择性沉淀钼、钨元素,有效消除基体元素钼、钨(沉淀率>95%)对Re定量干扰,同时不引入新干扰元素。相比现有分离富集前处理流程更加简便快捷,前处理时间缩短为现有方法的1/4;该方法对Re的检出限为6.9ng/g,采用国家一级标准物质钼矿石(GBW07238)、钼矿石(GBW07285)、铼钼矿石(GBW07373)和钨锡铋矿石(GBW07369)对方法的准确度进行了验证,测定值与推荐值吻合,相对误差为0.71%~6.07%,RSD<5%。本方法建立的“消解-分离富集”处理流程所需时间从常规的8~12h缩短至2h左右,在准确定量矿石样品中Re的同时简化了样品前处理流程,快速的样品处理及低廉的测试成本有助于关键稀有金属矿产的开发利用。