基于共被引方法的核材料研究前沿分析被引量：4

Analysis of Frontiers of Nuclear Material Based on Co-citation Method

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摘要 [目的/意义]旨在为中国核材料的研发决策提供参考。[方法/过程]以WOS数据库为数据源,基于CiteSpace用共被引分析和知识图谱等分析方法对核材料研究前沿进行分析。[结果/结论]近5年核材料研发前沿方向包括第四代核能系统、聚变堆、裂变聚变堆和加速器系统等,近一年的研发前沿是耐事故的包壳材料和铁铬铝合金。 [Purpose/significance]The paper is to provide references for decision making of research and development of nuclear material in China.[Method/process]The paper takes WOS as data resource,and uses co-citation and mapping knowledge domain to analyze the frontiers of nuclear material with CiteSpace.[Result/conclusion]The frontiers of nuclear materials in recent five years include the fourth generation of nuclear energy systems,fusion reactor,fission fusion reactor,and accelerator system;the frontiers in recent one year are accident resistant cladding material and FeCrAl alloy.

作者周波夏芸张徐璞杜静玲 Zhou Bo;Xia Yun;Zhang Xupu;Du Jingling(China Institute of Atomic Energy,Beijing 102413)

机构地区中国原子能科学研究院

出处《情报探索》 2019年第2期116-121,共6页 Information Research

关键词核材料文献计量学共被引分析 nuclear material bibliometrics co-citation analysis

分类号 G304 [文化科学]

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参考文献4

1李泽霞,黄龙光,李超,周丽英,冷伏海.核材料专利申请态势分析[J].科学观察,2013,8(6):30-43. 被引量：2
2吴学雁,艾丹祥,张延林.LED研究热点与前沿的知识图谱分析——基于SCIE中三种代表刊[J].情报杂志,2013,32(4):127-133. 被引量：9
3盛立,刘伟,李玉霞,刁天喜.合成生物学研究前沿的识别与趋势预测[J].军事医学,2015,39(2):143-146. 被引量：6
4张米娜,季叶克,张立昆,董靓.基于知识图谱的太阳能电池研究前沿探测分析[J].中国材料进展,2018,37(1):74-80. 被引量：4

二级参考文献23

1凌焱,段海清,陈惠鹏.合成生物学[J].军事医学科学院院刊,2006,30(6):572-574. 被引量：13
2Chen C. CiteSpace II: Detecting and Visualizing Emerging Trends and Transient Patterns in Scientific Literature[J]. Journal of the American Society for Information Science and Technolo- gy,2006,57 (3) :359-377.
3Chen C. The centrality of Pivotal Points in the Evolution of Sci- entific Networks [ A ] : In :Proceedings of the International Confer- ence on Intelligent User Interfaces ( IUI 2005 ) [ C ]. San Diego, CA ,2005.
4Dexter DL. A Theory of Sensitized Luminescence in Solids[ J]. Journal of Chemical Physics, 1953, 21 (5) : 836-851.
5Simon Sze, Physics of Semiconductor Devices[ M], New York: Wiley, 1981.
6Yamada M, Narukawa Y, Mukai T. Phosphor Free High-Lumi- nous-Efficiency White Light-Emitting Diodes Composed of In- GaN Multi - Quantum Well [J ]. Japanese Journal of Applied Physics, 2002,41:246-248.
7Adachi C, Baldo M A, Thompson ME. Nearly 100% Internal Phosphorescence Efficiency in an Organic Light-emitting Device [ J]. Journal of Applied Physics,2001,90(10) :5048-5051.
8Nakamura S, Senoh M. High-Brightness InGaN Blue, Green and Yellow Light-Emitting Diodes with Quantum Well Struc- tures[ J ]. Japanese Journal of Applied Physics, 1995,34 : 797 - 799.
9Tang CW. Organic electroluminescent diodes[ J]. Applied Phys- ics Letters,1987,51 (12) : 913-915.
10Fujii T. Increase in the extraction efficiency of GaN-based light- emitting Diodesvia Surface Roughening [ J ]. Applied Physics Letters,2004,84(6) : 855-857.