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姓名 王长乐 性别:
职称 副研究员 学位 博士
电话 010-82998184 传真: 010-62010846
Email: wangcl[a]mail.iggcas.ac.cn 邮编: 100029
地址 北京朝阳区北土城西路19号,中科院地质与地球物理研究所
更多信息:
 
简历:

  王长乐,副研究员,硕士生导师。1988年出生于湖北随州。2010年毕业于中国地质大学(武汉)资源勘查工程(固体矿产)专业获学士学位,2015年于手机新2会员端矿物学、岩石学、矿床学专业获博士学位。2015.6-2017.12留所从事博士后研究,2018年起,任该所副研究员。曾于2016.5-6和2017.3-5在英国伯明翰大学开展实验合作研究,2018年10月至2020年12月,美国耶鲁大学从事博士后研究。 
  主要研究领域为前寒武纪铁建造(IF)形成机制及其环境-生命效应的研究。通过系统研究,构建了华北早前寒武纪IF年代学格架,揭示了IF沉积盆地所在的构造背景与演化历史,成功约束了IF的沉积速率;发现华北条带状铁矿物质具多源性,创新性提出IF铁质主要受控于高温流体淋滤的古陆壳,并提出了IF中铁质与硅质来源不同,23亿年之前IF物质主要受控于热液淋滤的亏损地幔源区岩石;恢复了IF的原始矿物组成,建立了IF沉积矿物相的形成演化模式;系统诠释了早前寒武纪IF形成时的海洋氧化还原状态,极大丰富和完善BIF的成矿理论,结合建立的同位素反应模型,阐明了铬和铁的表生地球化学行为,解析了成岩过程中铬同位素的变化和水体中铁的氧化循环,直接定量了新太古代和中元古代大气的氧气浓度,极大加深了对早期地球充氧历史及其对生命演化进程制约的整体认知。
  在国内外学术刊物发表论文90篇,以第一/通讯作者在PNAS、EPSL、GCA(2)、EG(5)、MD(2)和AM等发表SCI论文32篇。


学术兼职:

中国矿物岩石地球化学学会第十届应用地球化学专业委员会委员(2022-2025)

 
学科类别:
地质学
 
研究方向:
  1. 沉积铁锰矿床及沉积环境
  2. 前寒武纪海洋和大气的氧化进程及对生命演化的启示
 
职务:
 
社会任职:
 
承担科研项目情况:

当前承担科研项目情况:

  1. 地质地球所重点部署项目
  2. 手机新2会员端基础与交叉前沿科研先导专项(B类)课题
  3. 手机新2会员端基金原创探索计划项目

已结题科研项目情况:

  1. 中国博士后科学基金面上资助
  2. 中国博士后科学基金会与手机新2会员端联合资助优秀博士后项目
  3. 手机新2会员端基金青年科学基金项目
  4. 手机新2会员端基金面上项目
  5. 手机新2会员端基础前沿科学研究计划从0到1原始创新项目
 
获奖及荣誉:
  1. 第五届全国应用地球化学学术会议优秀论文特等奖(2014)
  2. 手机新2会员端院长优秀奖(2015)
  3. 手机新2会员端大学三好学生(2015)
  4. 李四光优秀学生奖(2015)
  5. 手机新2会员端优秀博士学位论文(2016)
  6. 手机新2会员端青年创新促进会会员(2019)
  7. 手机新2会员端青年创新促进会优秀会员(2023)
 
代表论著:

   2024年

  1. Wang, C.L., Zhai, M.G., Robbins, L.J., Peng, Z.D., Zhang, X., Zhang, L.C., 2024. Late Archean shelf-to-basin iron shuttle contributes to the formation of the world-class Dataigou banded iron formation. Economic Geology, 119: 725-736.
  2. Wang, C.L., Peng, Z.D., Tong, X.X., Gao, L., Zhang, L.C., 2024. Geochemistry and Sm─Nd─Fe─Si isotope compositions as insights into the deposition of the late Neoarchean Qidashan banded iron formation, North China Craton. Mineralium Deposita, 59: 969-993.
  3. Wang, C.L., Xie, S.J., Zhang, X., Tong, X.X., Bai, Y., Peng, Z.D., Dong, Z.G., Zhang, L.C., Wan, B., 2024. Deciphering the source of banded iron formations in the North China Craton. Precambrian Research, 402: 107298.
  4. Dong, Z.G., Zhang, B.L., Gyollai, I., Fintor, K., Szabó, M., Kovács, I., Gao, J., Zhang, L.C., Polgári, M., Wang, C.L.*, 2024. Microbial contribution to the formation of the Carboniferous sedimentary manganese deposits in northwestern China. Ore Geology Reviews, 170: 106124.
  5. Xie, S.J., Dong, Z.G., Shang, J.B., Zhang, X., Peng, Z.D., Li, W., Zhang, L.C., Shi, Y.L., Robbins, L.J., Wang, C.L.*, 2024. Age and genesis of the Tongshan banded iron formation in the Zhongtiao region, North China Craton. Ore Geology Reviews, 164: 105845.
  6. Lechte, M., Halverson, G., Wallace, M., Gibson, T., Hood, A.V.S., Wang, C.L., Bui, T.H., Maloney, K., Millikin, A., 2024. Oolitic ironstones, continental iron flux and reverse weathering in the Proterozoic Eon: Insights from the Tonian Katherine Group, Yukon. Earth-Science Reviews, 104790.
  7. 王长乐, 高亮, 谢尚君, 张新, 彭自栋, 董志国, 白阳, 张连昌. 2024. 条带状铁建造的原始矿物组成:进展与问题. 岩石学报, 40(1): 79-96. 

    2023年
  8. Wang, C.L., Robbins, L.J., Planavsky, N.J., Beukes, N.J., Patry, L.A., Lalonde, S.V., Lechte, M.A., Asael, D., Reinhard, C.T., Zhang, L.C., Konhauser, K.O., 2023. Archean to early Paleoproterozoic iron formations document a transition in iron oxidation mechanisms. Geochimica et Cosmochimica Acta, 343: 286-303.
  9. Dong, Z.G., Peng, Z.D., Robbins, L.J., Konhauser, K.O., Zhang, B.L., Zhang, L.C., Li, J., Li, W.J., Zhang, L., Wang, C.L.*, 2023. Episodic ventilation of euxinic bottom waters triggers the formation of black shale-hosted Mn carbonate deposits. Geochimica et Cosmochimica Acta, 341: 132-149.
  10. Peng, Z.D., Nan, J.B., Zhang, L.C., Poulton, S., Zhou, J.L., Yuan, Y., Ta, K.W., Wang, C.L.*, Zhai, M.G., 2023. Evidence for abundant organic matter in a Neoarchean banded iron formation. American Mineralogist, 208(12): 2164-2181.
  11. Robbins, L.J., Fakhraee, M., Smith, A.J., Bishop, B.A., Swanner, E.D., Peacock, C.L., Wang, C.L., Planavsky, N.J., Reinhard, C.T., Crowe, S.A., Lyons, T.W., 2023. Manganese oxides, Earth surface oxygenation, and the rise of oxygenic photosynthesis. Earth-Science Reviews, 104368.
  12. Liu, S.K., Li, W.J., Su, B.X., Gao, B.Y., Wang, J., Wang, C.L., Luo, Y., Yan, L.Z., Zhao, Y., 2023. High-precision lithium isotopic analysis using the Nu Sapphire MC-ICP-MS. Journal of Analytical Atomic Spectrometry, 38: 656-666.
  13. Nan, J.B., Peng, Z.D., Wang, C., Papineau, D., She, Z.B., Guo, Z.X., Peng, X.T., Zhou, J.L., Hu, Y.J., Yao, W.Q., Zhang, R.L., Wang, C.L., Tao, R.B., 2023. Molecular mechanism of metamorphic alteration on traces of early life in banded iron formations. Earth and Planetary Science Letters, 615: 118226.
  14. Peng, Z.D., Wang, C.L., Zhang, L.C., Zhai, M.G., 2023. Decoupled neodymium and hafnium isotopes in seawater as insights into the Late Neoarchean weathering process. Precambrian Research, 397, 107170.
  15. 白阳, 张连昌, 朱明田, 黄柯, 高炳宇, 李文君, 王长乐. 2023. 华北克拉通北缘早白垩世金成矿与地幔物质的贡献. 岩石学报, 39(1): 217-235.
  16. 张连昌, 张爱奎, 刘永乐, 李文, 董志国, 高炳宇, 王长乐, 朱明田. 2023. 沉积岩-变沉积岩型钴矿研究进展与问题. 岩石学报, 39(4): 981-997. 
  17. 徐一帆, 董志国, 王长乐, 张连昌. 2023. 神奇而低调的锰——社会生活中的“配角”. 矿床地质, 42(6): 1310-1318.

    2022年

  18. Wang, C.L., Lechte, M.A., Reinhard, C.T., Asael, D., Cole, D.B., Halverson, G.P., Porter, S.M., Galili, N., Halevy, I., Rainbird, R.H., Lyons, T.W., Planavsky, N.J., 2022. Strong evidence for a weakly oxygenated ocean–atmosphere system during the Proterozoic. Proceedings of the National Academy of Sciences, 119(6): e2116101119.
  19. Mand, K., Planavsky, N.J., Porter, S.M., Robbins, L.J., Wang, C.L., Kreitsmann, T., Paiste, K., Romashkin, A.E., Deines, Y.E., Lepland, A., Konhauser, K.O., 2022. Chromium evidence for protracted oxygenation during the Paleoproterozoic. Earth and Planetary Science Letters, 584, 117501.
  20. Zhang, B.L., Lv, Z.C., Dong, Z.G., Zhang, X., Yu, X.F., Li, Y.S., Zhen, S.M., Wang, C.L.*, 2022. Source Characteristics of the Carboniferous Ortokarnash Manganese Deposit in the Western Kunlun Mountains. Minerals, 12, 786.
  21. Peng, Z.D., Wang, C.L.*, Poulton, S.W., Tong, X.X., Konhauser, K.O., Zhang, L.C., 2022. Origin of the Neoarchean VMS-BIF Metallogenic Association in the Qingyuan Greenstone Belt, North China Craton: Constraints from Geology, Geochemistry, and Iron and Multiple Sulfur (δ33S, δ34S, and δ36S) Isotopes. Economic Geology, 117(6), 1275-1298.
  22. Dong, Z.G., Peng, Z.D., Wang, C.L.*, Zhang, B.L., Zhang, L.C., Li, J., Zhang, X., Li, W.J., Zhang, L., 2022. Insight into the genesis of the Zhaosu Carboniferous Mn carbonate deposit (NW China): constraints from petrography, geochemistry, and C–Mo isotopes. Mineralium Deposita, 57, 1269-1289.
  23. 张连昌, 董志国, 张帮禄, 李文君, 彭自栋, 王长乐, 朱明田. 2022. 西昆仑“玛尔坎苏式”富锰矿主控因素及成矿模式. 地质学报, 96(9), 3195-3210.
  24. 张帮禄, 张连昌, 董志国, 彭自栋, 朱明田, 王长乐. 2022. 西昆仑地区古生代沉积型铁锰矿床成矿规律及其与原—古特提斯洋演化的关系. 地质科学, 57(4): 1047-1063.
  25. 张连昌, 冯京, 李平, 朱明田, 董志国, 高炳宇, 张新, 王长乐, 陈博, 计文化. 2022. 西天山构造演化与优势矿产成矿规律. 地球科学, 47(9): 3127-3146.
  26. 张新, 董志国, 彭自栋, 张连昌, 张帮禄, 王长乐*. 2022. 西天山石炭纪式可布台铁矿沉积-成岩过程: 岩相学与矿物学的证据. 岩石学报, 38(10): 3125-3142.
        
    2021年
  27. Wang, C.L., Christopher Reinhard, Kyle Rybacki, Dalton Hardisty, Frantz Ossa Ossa, Wang, X.L., Axel Hofmann, Dan Asael, Leslie Robbins, Zhang, L.C., Noah Planavsky, 2021. Chromium isotope systematics and the diagenesis of marine carbonates. Earth and Planetary Science Letters, 562: 116824.
  28. Tong, X.X., Wang, C.L.*, Peng, Z.D., Li, Y.H., Hao, W.D., M?nd, K., Robbins, L.J., Zhang, L.C., Ke, Q., Zhai, M.G., and Konhauser, K.O., 2021. Depositional and environmental constraints on the late Neoarchean Dagushan deposit (Anshan-Benxi area, North China Craton): An Algoma-type banded iron formation. Economic Geology, 116(7): 1575-1597.
  29. Tong, X.X., M?nd, K., Li, Y., Zhang, L.C., Peng, Z.D., Wu, Q., Li, P.B., Zhai, M.G., Leslie Robbins, Wang, C.L.*, Konhauser, K. O. (2021). Iron and Carbon Isotope Constraints on the Formation Pathway of Iron-Rich Carbonates within the Dagushan Iron Formation, North China Craton. Minerals, 11(1), 94.
  30. Peng, Z.D., Zheng, M.T., Wang, C.L., Zhang, L.C., Fan, L.G., Tong, X.X., 2021. Constraints on the age and geodynamic setting of the iron formations and anhydrite Fe-(Ba) deposits in the Bulunkuole Group of the Taxkorgan area, NW China. Ore Geology Reviews, 104121.
  31. Soh, A.P.D., Ganno, S., Zhang, L.C., Tamehe, L.S., Wang, C.L., Peng, Z.D., Tong, X.X., Nzenti, J.P., 2021. Origin, tectonic environment and age of the Bibole banded iron formations, northwestern Congo Craton, Cameroon: geochemical and geochronological constraints. Geological Magazine, 1-19.
  32. Zhang, Y.Y., Planavsky, N.J., Zhao, M.Y., Isson, T., Asael, D., Wang, C.L., Wang, F., 2021. The isotopic composition of sedimentary organic zinc and implications for the global Zn isotope mass balance. Geochimica et Cosmochimica Acta, 314: 16-26.
  33. 董志国, 张帮禄, 石方平, 张连昌, 高炳宇, 张新, 彭自栋, 王长乐. 2021. 新疆西天山莫托萨拉热水沉积型铁锰矿床矿物学与地球化学特征. 岩石学报, 37(4), 1099-1121.

    2020年
  34. Zhang, B.L., Wang, C.L., Robbins, L.J., Zhang, L.C., Konhauser, K.O., Dong, Z.G., Li, W.J., Peng, Z.D., Zheng, M.T., 2020. Petrography and Geochemistry of the Carboniferous Ortokarnash Manganese Deposit in the Western Kunlun Mountains, Xinjiang Province, China: Implications for the Depositional Environment and the Origin of Mineralization. Economic Geology, 115(7), 1559-1588.
  35. 张连昌, 彭自栋, 翟明国, 佟小雪, 朱明田, 王长乐. 2020. 华北克拉通北缘新太古代清原绿岩带BIF与VMS共生矿床的构造背景及成因联系. 地球科学, 45(1): 1-16.
  36. 董志国, 张连昌, 董飞羽, 张帮禄, 谢月桥, 查斌, 彭自栋, 王长乐. 2020. 西昆仑穆呼锰矿床地质特征, 控矿因素及成矿模式. 吉林大学学报 (地球科学版), 50(5): 1358-1372.
  37. 张连昌, 张帮禄, 董志国, 谢月桥, 李文君, 彭自栋, 朱明田, 王长乐. 2020. 西昆仑玛尔坎苏石炭纪大型锰矿带构造背景与成矿条件. 吉林大学学报 (地球科学版), 50(5): 1340-1357.
  38. 董志国, 张连昌, 王长乐, 张帮禄, 彭自栋, 朱明田, 冯京, 谢月桥. 2020. 沉积碳酸锰矿床研究进展及有待深入探讨的若干问题. 矿床地质, 39(2): 237-255.
  39. 张连昌, 兰彩云, 王长乐, 彭自栋, 佟小雪, 李文君, 董志国. 2020. 古元古代大氧化事件(GOE)前后海洋环境的变化: 来自华北条带状铁建造(BIF)岩相学和地球化学的证据. 古地理学报, 22(5): 827-840.
        
    2019年
  40. Lan, C.Y., Yang, A.Y., Wang, C.L., Zhao, T.P., 2019. Geochemistry, U-Pb zircon geochronology and Sm-Nd isotopes of the Xincai banded iron formation in the southern margin of the North China Craton: Implications on Neoarchean seawater compositions and solute sources. Precambrian Research, 326: 240-257.
  41. Peng, Z.D., Wang, C.L.*, Zhang, L.C., Zhu, M.T., Tong, X.X., 2019. Geochemistry of metamorphosed volcanic rocks in the Neoarchean Qingyuan greenstone belt, North China Craton: Implications for geodynamic evolution and VMS mineralization. Precambrian Research, 326: 196-221.
  42. Tong, X.X., Wang, C.L.*, Peng, Z.D., Huang, H., Zhang, L.C., Zhai, M.G., 2019. Geochemistry of meta-sedimentary rocks associated with the Neoarchean Dagushan BIF in the Anshan-Benxi area, North China Craton: Implications for their provenance and tectonic setting. Precambrian Research, 325: 172-191.
        
    2018年
  43. Zheng, M.T., Wang, C.L.*, Zhang, L.C., Shi, Z.B., Zhu, M.T., Li, Z.Q., He, L.D., 2018. Geological and geochemical constraints on the origin of the Early Cambrian Kalaizi Fe-Ba deposit in Western Kunlun, NW China. Ore Geology Reviews, 100: 347-359.
  44. Zhu, M.T., Peng, Z.D., Zhang, L.C., Wang, C.L., 2018. Reply to a comment on "In situ zircon U-Pb dating and O isotopes of the Neoarchean Hongtoushan VMS Cu-Zn deposit in the North China Craton: Implication for the ore genesis" by Ming-Tian Zhu et al. [Ore Geol. Rev. 67 (2015) 354–367]. Ore Geology Reviews, 95: 1181-1184.
  45. Peng, Z.D., Tong, X.X., Wang, C.L.*, 2018. Meso- and Neoarchean Banded Iron Formations and Genesis of High-Grade Magnetite Ores in the Anshan-Benxi Area, North China Craton—A Discussion. Economic Geology, 113(4): 989-993.
  46. Peng, Z.D., Wang, C.L.*, Tong, X.X., Zhang, L.C., Zhang, B.L., 2018. Element geochemistry and neodymium isotope systematics of the Neoarchean banded iron formations in the Qingyuan greenstone belt, North China Craton. Ore Geology Reviews, 102: 562-584.
  47. 彭自栋, 张连昌, 王长乐, 佟小雪, 南景博. 2018. 新太古代清原绿岩带下甸子BIF铁矿地质特征及含黄铁矿条带BIF的成因探讨. 岩石学报, 34(2): 398-426.
  48. 佟小雪, 王长乐, 彭自栋, 南景博, 黄华, 张连昌. 2018. 早前寒武纪BIF原生矿物组成及演化、沉积相模式研究进展. 地球科学进展, 33(2): 152-165.
  49. 佟小雪, 张连昌, 王长乐, 彭自栋, 南景博. 2018. 鞍本地区大孤山条带状铁建造含铁矿物和相分带特征及形成环境分析. 岩石学报, 34(4): 1119-1138.
  50. 王长乐, 张连昌, 佟小雪, 2018. BIF铁矿形成时代与物质来源. 华北克拉通前寒武纪重大地质事件与成矿(翟明国等著), 科学出版社, 1-543.
  51. 张连昌, 王长乐, 彭自栋, 2018. BIF铁矿的形成环境与形成机制. 华北克拉通前寒武纪重大地质事件与成矿(翟明国等著), 科学出版社, 1-543.
        
    2017年    
  52. Wang, C.L., Peng, Z.D., Tong, X.X., Huang, H., Zheng, M.T., Zhang, L.C., Zhai, M.G., 2017. Late Neoarchean supracrustal rocks from the Anshan-Benxi terrane, North China Craton: New geodynamic implications from the geochemical record. American Journal of Science, 317: 1095-1148.
  53. Wang, C.L., Wu, H.Y., Li, W.J., Peng, Z.D., Zhang, L.C., Zhai, M.G., 2017. Changes of Ge/Si, REE+Y and Sm-Nd isotopes in alternating Fe- and Si-rich mesobands reveal source heterogeneity of the ~2.54 Ga Sijiaying banded iron formation in Eastern Hebei, China. Ore Geology Reviews, 80: 363-376.
  54. Huang, H., Zhang, L.C., Fabre, S., Wang, C.L., Zhai, M.G., 2017. Depositional environment and origin of the Lilaozhuang Neoarchean BIF-hosted iron–magnesite deposit on the southern margin of the North China Craton. International Journal of Earth Sciences, 106: 1753-1772.
  55. Lan, C.Y., Zhou, Y.Y., Wang, C.L., Zhao, T.P., 2017. Depositional age and protoliths of the Paleoproterozoic upper Taihua Group in the Wuyang area in the southern margin of the North China Craton: New insights into stratigraphic subdivision and tectonic setting. Precambrian Research, 297: 77-100.
  56. Zhu, M.T., Zhang, L.C., Dai, Y.P., Wang, C.L., Peng, Z.D., 2017. Hydrothermal modification of zircon geochemistry and Lu–Hf isotopes from the Hongtoushan Cu–Zn deposit, China. Ore Geology Reviews, 86: 707-718.
  57. 南景博, 黄华, 王长乐, 彭自栋, 佟小雪, 张连昌. 2017. 内蒙古固阳绿岩带条带状铁建造地球化学特征与沉积环境讨论. 中国地质, 2: 331-345.
  58. 彭自栋, 王长乐, 赵刚, 朱明田, 张连昌, 佟小雪, 南景博. 2017. 前寒武纪VMS与BIF铁矿床共生组合研究进展. 矿床地质, 36(4): 905-920.
        
    2016年    
  59. Wang, C.L., Huang, H., Tong, X.X., Zheng, M.T., Peng, Z.D., Nan, J.B., Zhang, L.C., Zhai, M.G., 2016. Changing provenance of late Neoarchean metasedimentary rocks in the Anshan-Benxi area, North China Craton: Implications for the tectonic setting of the world-class Dataigou banded iron formation. Gondwana Research, 40: 107-123.
  60. Wang, C.L., Konhauser K.O., Zhang L.C., Zhai M.G., Li W.J., 2016. Decoupled sources of the 2.3-2.2 Ga Yuanjiacun banded iron formation: Implications for the Nd cycle in Earth’s early oceans. Precambrian Research, 280: 1-13.
  61. Wang, C.L., Zhang, L.C., 2016. A Genetic Link between Paleoproterozoic Yuanjiacun BIF and the Great Oxidation Event in North China Craton. In MG Zhai, Y Zhao and TP Zhao (ed.) Main Tectonic Events and Metallogeny of the North China Craton. Springer Singapore, 329-356.
  62. Zhang, L.C., Wang, C.L., Zhu, M.T., Huang, H., Peng, Z.D., 2016. Neoarchean Banded Iron Formations in the North China Craton: Geology, Geochemistry, and Its Implications. In MG Zhai, Y Zhao and TP Zhao (ed.) Main Tectonic Events and Metallogeny of the North China Craton. Springer Singapore, 85-103.
  63. Li, W.J., Wang, C.L., Gao, B.Y., Wang, Y.T., Jin, X.D., Zhang, L.C., Sakyi, P.A., 2016. Determination of multi-element concentrations at ultra-low levels in alternating magnetite and pyrite by HR-ICP-MS using matrix removal and preconcentration. Microchemical Journal, 127: 237-246.
  64. 代堰锫, 朱玉娣, 张连昌, 王长乐, 陈超, 修迪. 2016. 国内外前寒武纪条带状铁建造研究现状. 地质论评, 62(3): 735-757.
        
    2015年    
  65. Wang, C.L., Zhang, L.C., Dai, Y.P., Lan, C.Y., 2015. Geochronological and geochemical constraints on the origin of clastic meta-sedimentary rocks associated with the Yuanjiacun BIF from the Lüliang Complex, North China. Lithos, 212-215: 231-246.
  66. Wang, C.L., Konhauser, K.O., Zhang, L.C., 2015. Depositional Environment of the Paleoproterozoic Yuanjiacun Banded Iron Formation in Shanxi Province, China. Economic Geology, 110: 1515-1539.
  67. 王长乐, 张连昌, 兰彩云, 代堰锫, 李红中, 黄华. 2015. 山西吕梁袁家村条带状铁建造沉积相与沉积环境分析. 岩石学报, 31(6): 1671-1693.
  68. Zhu, M.T., Dai, Y.P., Zhang, L.C., Wang, C.L., Liu, L., 2015. Geochronology and geochemistry of the Nanfen iron deposit in the Anshan-Benxi area, North China Craton: Implications for ~2.55 Ga crustal growth and the genesis of high-grade iron ores. Precambrian Research, 260: 23-38.
  69. Zhu, M.T., Zhang, L.C., Dai, Y.P., Wang, C.L., 2015. In situ zircon U–Pb dating and O isotopes of the Neoarchean Hongtoushan VMS Cu–Zn deposit in the North China Craton: Implication for the ore genesis. Ore Geology Review, 67: 354-367.
  70. Wu, H.Y., Niu, X.L., Zhang, L.C., Pirajno, F., Luo, H.B., Qin, F, Cui, M.L., Wang, C.L., Qi, M., 2015. Geology and geochemistry of the Macheng Algoma-type banded iron-formation, North China Craton: Constraints on mineralization events and genesis of high-grade iron ores. Journal of Asian Earth Sciences,113: 1179-1196.
  71. 郑梦天, 张连昌, 王长乐, 朱明田, 李智泉, 王亚婷. 2015. 冀东杏山BIF铁矿形成时代及成因探讨. 岩石学报, 31(6): 1636-1652.
  72. 兰彩云, 赵太平, 罗正传, 王长乐, 文启付, 刘立新. 2015. 河南舞阳赵案庄铁矿床成因:来自磁铁矿和磷灰石的矿物学证据. 岩石学报, 31(6): 1653-1670.
        
    2014年    
  73. Wang, C.L., Zhang, L.C., Lan, C.Y., Dai, Y.P., 2014. Rare Earth Element and yttrium compositions of the Paleoproterozoic Yuanjiacun BIF in the Lüliang area and their implications for the Great Oxidation Event (GOE). SCIENCE CHINA Earth sciences, 57: 2469-2485.
  74. Wang, C.L., Zhang, L.C., Dai, Y.P., Li, W.J., 2014. Source characteristics of the ~2.5 Ga Wangjiazhuang Banded Iron Formation from the Wutai greenstone belt in the North China Craton: Evidence from neodymium isotopes. Journal of Asian Earth Sciences, 93: 288-300.
  75. Wang, C.L., Zhang, L.C., Lan, C.Y., Dai, Y.P., 2014. Petrology and geochemistry of the Wangjiazhuang banded iron formation and associated supracrustal rocks from the Wutai greenstone belt in the North China Craton: Implications for their origin and tectonic setting. Precambrian Research, 255: 603-626.
  76. 王长乐, 张连昌, 刘利, 代堰锫. 2014. 条带状铁建造(BIF)的形成时代及其研究方法. 地质科学, 49(4): 1201-1215.
  77. 王长乐, 张连昌, 兰彩云, 代堰锫. 2014. 山西吕梁古元古代袁家村铁矿BIF稀土元素地球化学及其对大氧化事件的指示. 中国科学:地球科学, 44: 2389-2405.
  78. Dai, Y.P., Zhang, L.C., Zhu, M.T., Wang, C.L., Liu, L., Xiang, P., 2014. The composition and genesis of Mesoarchean Dagushan banded iron formation (BIF) in the Anshan area of the North China Craton. Ore Geology Review, 63: 353-373.
  79. Li, H.Z., Zhai, M.G., Zhang, L.C., Yang, Z.J., Kapsiotis, A., Zhou, Y.Z., He, J.G., Wang, C.L., Liang, J., 2014. Mineralogical and microfabric characteristics of magnetite in the Wuyang Precambrian BIFs, southern North China Craton: Implications for genesis and depositional processes of the associated BIFs. Journal of Asian Earth Sciences, 94: 267-281.
  80. Li, W.J., Jin, X.D., Gao, B.Y., Wang, C.L., Zhang, L.C., 2014. Analysis of ultra-low level Rare Earth Elements in magnetite samples from banded iron formations using HR-ICP-MS after chemical separation. Analytical Methods, 6: 6125-6132.
  81. 张连昌, 代堰锫, 王长乐, 刘利, 朱明田. 2014. 鞍山—本溪地区前寒武纪条带状铁建造铁矿时代、物质来源与形成环境. 地球科学与环境学报, 36(04): 1-15.
        
    2013年    
  82. 代堰锫, 张连昌, 朱明田, 王长乐, 刘利. 2013. 鞍山陈台沟BIF铁矿与太古代地壳增生: 锆石U-Pb年龄与Hf同位素约束. 岩石学报, 29(7): 2537-2550.
  83. 兰彩云, 张连昌, 赵太平, 王长乐, 李红中, 周艳艳. 2013. 河南舞阳铁山庙式 BIF 铁矿的矿物学与地球化学特征及对矿床成因的指示. 岩石学报, 29(7): 2567-2582.
  84. 李红中, 翟明国, 张连昌, 杨志军, 周永章, 王长乐, 梁锦, 罗安. 2013. 华北克拉通南缘舞阳地区太古代BIF方解石的微区特征及地质意义研究. 光谱学与光谱分析, 33(11): 3061-3065.
        
    2012年    
  85. 王长乐, 张连昌, 刘利, 代堰锫. 2012. 国外前寒武纪铁建造的研究进展与有待深入探讨的问题. 矿床地质, 31(6): 1311-1325.
  86. Zhang, L.C., Zhai, M.G., Zhang, X.J., Xiang, P., Dai, Y.P., Wang, C.L., Pirajno, F., 2012. Formation age and tectonic setting of the Shirengou Neoarchean banded iron deposit in eastern Hebei Province: Constraints from geochemistry and SIMS zircon U-Pb dating. Precambrian Research, 222-223: 325-338.
  87. 张连昌, 翟明国, 万渝生, 郭敬辉, 代堰锫, 王长乐, 刘利. 2012. 华北克拉通前寒武纪BIF铁矿研究:进展与问题. 岩石学报, 28(11): 3431-3445.
  88. 刘利, 张连昌, 代堰锫, 王长乐, 李智泉. 2012. 内蒙古固阳绿岩带三合明BIF型铁矿的形成时代、地球化学特征及地质意义. 岩石学报, 28(11): 3623-3637.
  89. 代堰锫, 张连昌, 王长乐, 刘利, 崔敏利, 朱明田, 相鹏. 2012. 辽宁本溪歪头山条带状铁矿的成因类型、形成时代及构造背景. 岩石学报, 28(11): 3574-3594.
  90. 李文君, 靳新娣, 崔敏利, 王长乐. 2012. BIF微量稀土元素分析方法及其在冀东司家营铁矿中的应用. 岩石学报, 28(11): 3670-3678.
 

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