Research Progress on In-situ U-Pb Dating of Uranium-rich Minerals: A Visualization Analysis of Knowledge Graphs Based on CiteSpace
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摘要:
富铀矿物U-Pb体系微区原位定年技术在地球系统科学和自然资源综合地质调查中具有广泛的应用。为全面梳理其研究进展,探讨研究热点和发展趋势,本文利用CiteSpace对Web of Science核心数据库(WOS)和维普数据库(VIP)中1991—2024年期间共
20469 篇相关文献进行可视化分析,得到了相关知识图谱。结果表明,U-Pb微区原位定年分析领域的发展可大致分为3个阶段:起步阶段(1991—2001年)、快速发展阶段(2002—2018年)、稳定发展阶段(2019年—),主要取决于测试仪器、定年矿物拓展和数据处理软件三方面的进步。基于上述图谱分析,对U-Pb微区原位定年分析方法及其应用研究进展进行了总结,指出该领域前沿热点为不同矿物U-Pb定年的方法研发与应用拓展,下一步研究方向主要有以下几点:(1)应用飞秒激光和缩小一次离子束等技术以提高测试仪器的灵敏度、分析精度和空间分辨率;(2)研发高效的U-Pb预扫描技术并深入研究U和Pb在矿物中的赋存状态,完善低U矿物的微区原位分析方法;(3)研制不同组成不同年龄的标准物质,或建立非基体匹配方法,解决某些定年矿物标准样品稀缺的问题;(4)建立新矿物的U-Pb微区原位分析方法,尤其是沉积岩和矿床中的矿物,进一步拓展其应用领域;(5)研发基于AI的智能数据处理软件,避免数据处理过程中的主观影响。Abstract:The in-situ U-Pb dating of uranium-rich minerals has extensive applications in geoscience and integrated geological surveys of natural resources. To comprehensively review its research progress and explore the research hotspots and development trends, this study utilized CiteSpace to conduct a visualization analysis of 20,469 related articles from the Web of Science Core Collection (WOS) and the VIP Database from 1991 to 2024, generating relevant knowledge graphs. The results indicate that the development of in-situ U-Pb dating can be broadly divided into three stages: the initial stage (1991—2001), the rapid development stage (2002—2018), and the stable development stage (2019—present). This progress has primarily been driven by advancements in three key areas: analytical instruments, the expansion of dating minerals, and data processing software. Based on the above visualization analysis, this paper summarizes the research progress in in-situ U-Pb dating methods and their applications. It highlights that the current research frontier focuses on the method development and application expansion of U-Pb dating utilization for various minerals. The future research directions include the following: (1) Applying femtosecond laser and reducing the primary ion beam size to enhance the sensitivity, accuracy and spatial resolution of instruments; (2) Developing efficient U-Pb pre-scanning techniques and further investigating the occurrence states of U and Pb in minerals to improve in-situ dating methods of low U minerals; (3) Developing reference materials with diverse compositions and ages, or establishing non-matrix-matched methods to address the scarcity of reference materials for certain dating minerals; (4) Establishing in-situ U-Pb dating methods for new minerals, especially those in sedimentary rocks and ore deposits, and expanding their application fields further; (5) Building AI-based intelligent data processing software to eliminate subjective influences in data processing.
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Key words:
- U-Pb /
- in-situ dating /
- uranium-rich minerals /
- research progress /
- CiteSpace
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表 1 文献样本统计表
Table 1. Statistical of Literature samples
数据库 Web of Science核心数据库(WOS) 维普数据库(VIP) 搜索项目 Topic 任意字段 搜索字段 字段1:U-Pb
字段2:LA-ICP-MS OR LA-MC-ICP-MS
OR SHRIMP OR Cameca OR in-situ OR EPMA字段1:"U-Pb" + "铀-铅"
字段2:"LA-ICP-MS" + "LA-MC-ICP-MS" + "SHRIMP" +
"CAMECA" +"EPMA" + "in-situ analysis" + "微区原位分析"限制条件 时间段1991—2024年
文章类型为Article和Review时间段1991—2023年
文章类型为文献和综述
学科限定为天文地球搜索结果 12661 条8507 条(含英文版)除重结果 12614 条7855 条(剔除英文版)
下载: 导出CSV
表 2 被引数前十的文献
Table 2. Top ten most cited references
被引数 作者 DOI 主要内容 332 Liu Y S et al.(2010a) 10.1093 /petrology/egp082ICPData Cal 310 Vermeesch(2018) 10.1016 /j.gsf.2018.04.00IsoplotR 272 Ludwig(2012) 10.12691 /JGG-5-3-3Isoplot 182 Zhai M G and Santosh.(2011) 10.1016 /j.gr.2011.02.005华北克拉通相关综述 174 Liu Y S et al.(2008) 10.1016 /j.chemgeo.2008.08.004主微量元素分析(常与U-Pb分析共同使用) 159 Wu F Y et al.(2006) 10.1016 /j.chemgeo.2006.05.003斜锆石U-Pb年代学与锆石标准Hf同位素 151 Black et al.(2003) 10.1016 /S0009-2541 (03)00165-7锆石标样TEMORA 1 151 Liu Y S et al.(2010b) 10.1007 /s11434-010-3052 -4锆石U-Pb定年方法改进 144 Zhao G C and Zhai M G (2013) 10.1016 /j.gr.2012.08.016华北克拉通相关综述 136 Whitney and Evans(2010) 10.2138 /am.2010.3371矿物名称缩写汇总(常用于岩矿鉴定等
U-Pb分析的前期准备工作)注:被引数仅代表该文献在研究样本中的被引用次数,不代表实际被引用次数
下载: 导出CSV
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