ICF物理实验用纳米Cu块体靶材的制备研究

楚广; 唐永建; 罗江山; 刘伟; 杨天足; 黎军; 洪伟

强激光与粒子束, 2005, 17 (12): 1829, 网络出版: 2006-04-28

ICF物理实验用纳米Cu块体靶材的制备研究

Preparation synthesis of nanocrystalline copper target material for ICF experiments

论文大纲

楚广 ^1,2唐永建 ²罗江山 ²刘伟 ^2,3杨天足 ¹黎军 ²洪伟 ²

作者单位

¹ 中南大学冶金科学与工程学院,湖南,长沙,410083

² 中国工程物理研究院激光聚变研究中心,四川,绵阳,621900

³ 西南科技大学材料科学与工程学院四川,绵阳621010

摘要

采用自悬浮定向流法制备了金属纳米粉体并采用真空手套箱专利技术和冷压法在高压(1.5GPa)作用下保压40min后,成功制备出了相对密度达97%和显微硬度达1.85GPa的金属Cu纳米晶材料.经XRD分析,其晶粒大小为20nm.正电子湮没(PAS)实验结果表明,其空隙大小和数量与采用惰性气体冷凝法原位压制(IGC)的样品相比,空位簇数量较多,微空隙的大小和数量基本相当.激光惯性约束聚变(ICF)模拟实验表明:采用该方法制备的纳米Cu块体材料靶的激光转换效率比常规Cu材料靶高5倍.

Abstract

Copper nano-particles were prepared by flow-levitation method and compacted for 40 min under pressure of 1.5 GPa by cold pressing method.The pressing process was studied well under 25 ℃ and inert gas protection.The relative density and the microhardess of a specimen were 97% and 1.85 GPa,respectivity.XRD analysis showed that the average grain size of the specimens was 20 nm.The positron annihilation spectroscopy(PAS) results showed that the size and amount of the vacancies and microvoids were similar to those of the nanocrystalline Cu prepaered by inert gas condensation method(IGC) but more large voids.The simulation experiment of inertial confinement fusion indicated that the efficiency of K_α-ray conversed from laser with nanocrystalline Cu was 5 times higher than that of coarse-grained Cu.

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楚广, 唐永建, 罗江山, 刘伟, 杨天足, 黎军, 洪伟. ICF物理实验用纳米Cu块体靶材的制备研究[J]. 强激光与粒子束, 2005, 17(12): 1829. CHU Guang, TANG Yong-jian, LUO Jiang-shan, LIU Wei, YANG Tian-zu, LI Jun, HONG Wei. Preparation synthesis of nanocrystalline copper target material for ICF experiments[J]. High Power Laser and Particle Beams, 2005, 17(12): 1829.

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