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姓名: 王华建 性别:
职称: 特聘研究员 学历: 博士
电话: - 传真: 010-62010846
Email: wanghuajian@mail.iggcas.ac.cn 邮编: 100029
地址: 北京朝阳区北土城西路19号,中国科学院地质与地球物理研究所
更多信息:

English】 深层油气理论与智能勘探开发重点实验室>油气理论与方法学科中心 多圈层物质与能量交换学科组
【Research Gate】Huajian Wang
 
简历:

王华建,男,主要从事油气地质和地球化学研究。针对全球油气勘探向深层-超深层和非常规领域拓展的重大需求,开展了从中元古代至白垩纪的长尺度油气地质基础研究,在早期海洋碳循环模型和深层油气源、页岩有机质和页岩油富集模式、核反应堆辐照实验和放射性生烃-生氢机理等方面取得了系列创新认识,为揭示环境‒生命协同演化及其油气资源效应、服务油气勘探新领域的区带优选与靶层预测提供了重要科学依据。在PNAS、EPSL、Energy & Fuels(封面)、中国科学:地球科学(封面)、石油勘探与开发等国内外知名学术期刊发表学术论文100余篇,其中第一/通讯作者30余篇,文章被引用3000多次,第一发明人获授权国家发明专利4项,并荣获侯德封矿物岩石地球化学青年科学家奖(2023),中国石油天然气集团公司科技进步特等奖(2016)和一等奖(2022)等科技奖励和荣誉。

教育经历
  2002-2006:中国海洋大学  化学  学士
  2006-2011:中国科学院高能物理研究所  生物无机化学  博士

工作经历
  2011-2024:中国石油勘探开发研究院 博士后/工程师/高级工程师
  2024至今:中国科学院地质与地球物理研究所  特聘副研究员/特聘研究员

学术服务
  中国检验检测学会测试装备分会原子光谱应用与技术专家组委员(2023−2028)
  中国古生物学会新技术新方法专业委员会委员(2024-2028)
  中国石油学会微生物资源与工程技术专业委员会委员(2024−2029)
 
研究方向:
  1. 有机碳循环路径及地质驱动因素
  2. 地质微生物作用及油气资源效应
  3. 烃源岩评价方法和创新实验技术
 
学科类别:
油气地质动力学
 
职务:
 
社会任职:
 
获奖及荣誉:
  1. 侯德封矿物岩石地球化学青年科学家奖(2023)
  2. 中国石油勘探开发研究院先进工作者(2023)
  3. 中国管理科学学会管理科学奖(实践奖)(R6,2024)
  4. 中国石油天然气集团公司科技进步特等奖(R7,2016)和一等奖(R19、2022)
 
承担科研项目情况:
  1. 中国科学院青年人才项目(2025-2029)
  2. 国家自然科学基金面上(2024-2027、2019-2022)、青年(2017-2019)和专项(2024-2025)项目
  3. 国家重点研发计划项目子课题(2021-2027)
  4. 中国博士后科学基金面上资助(2012-2013)
 
代表论著:

2015年以来论文发表情况(#为共同第一作者,*为通讯作者)

2026年

  95. 朱日祥*, 王华建, 张旺, 赵盼, 柳宇柯, 王永莉, 王晓梅, 赵亮, 金之钧, 郝芳, 张水昌, 2026. 白垩系全球油气富集的多圈层驱动机制. 地学前缘, 1-19.

2025

  94. Wang, H., Liu, Z., Li, S., Liu, Y., Gao, S., Lyu, Y., Wu, H., Zhang, S.*, 2025. Transmission mechanism from orbital forced climate change to organic matter and shale oil enrichment: A case study of Gulong shale oil in the Cretaceous Qingshankou Formation, Songliao Basin, NE China. Petroleum Exploration and Development, 52(5): 1222-1234. 王华建, 刘真吾, 李山, 柳宇柯, 高爽, 吕亦然, 吴怀春, 张水昌*, 2025. 从轨道强迫气候变化到有机质和页岩油富集的传递机制——以松辽盆地白垩系青山口组古龙页岩油为例. 石油勘探与开发, 52(5): 1080-1091.

  93. Gao, S., Wang, H.*, Hao, J., Li, Y.*, 2025. In-situ micro-scale analysis of pyrite morphology and sulfur isotopes in the Cretaceous lacustrine shale. Atomic Spectroscopy, 46(4): 438-445.

  92. Zhu, R.*, Zhang, W., Wang, H., Li, J., Hu, Q., Zhao, L., Wang, X., Zhang, S., Hao, F., Jin, Z., 2025. A theory of multi-spheric interaction-driven hydrocarbon formation and enrichment. Sci. China Earth Sci. 68(8), 2492-2510. 朱日祥*, 张旺, 王华建, 李继磊, 胡清扬, 赵亮, 王晓梅, 张水昌, 郝芳, 金之钧, 2025. 多圈层驱动的油气形成与富集理论. 中国科学: 地球科学 55(8), 2603-2620.

  91. Zhao, L.*, Zhu, R., Shen, H., Liu, S., Yang, J., Wang, H., Zhang, W., Sun, B., 2025. Deep processes and surface effects of the Meso-Cenozoic Caribbean subduction system. Science China-Earth Sciences, 68(7): 2154-2167. 赵亮×, 朱日祥, 沈昊, 刘少辉, 杨建锋, 王华建, 张旺, 孙宝璐, 2025. 中新生代加勒比地区俯冲体系深部过程与浅部效应. 中国科学: 地球科学, 55(07): 2226-2240.

  90. 高爽, 李勇*, 刘乐, 王华建, 2025. 泥炭(成煤)沼泽古野火记录及碳循环效应. 沉积学报, 1-26.

  89. Qiu, R., Bao, X.*, Kemp, D.B., Guo, J., Yuan, S., Zhang, W.*, Wang, H., Liu, M., Zhang, R., Wan, B., Zhao, L., Hu, Y., Jin, Z., 2025. Elevated atmospheric CO2 drove spatial variability in terrestrial organic carbon burial during the Toarcian hyperthermal. Communications Earth & Environment, 6(1): 700.

  88. Song, Y.*, Mills, B.J.W., Bowyer, F.T., Andersen, M.B., Ossa, F.O., Dickson, A.J., Harvey, J., Zhang, S., Wang, X., Wang, H., Canfield, D.E., Shields, G.A., Poulton, S.W., 2025. Tracking the spatial extent of redox variability in the mid-Proterozoic ocean. Geology, 53(9), 785–789.

  87.Liu, Y.,Wang, H.*, Zhang, J., Ye, Y., Wang, X. and Zhang, S., 2025. Uncover the diagenetic water condition and dolomite formation in the Songliao Basin 91 Ma. Journal of Earth Science, 36(3): 1109–1128.

  86. Li, X., Crockford, P.W., Song, Y.*, Yin, H., Wei, W., Wang, X., Ye, Y., Jing, Z., Huang, F.,Wang, H.*,Hao, J.*, 2025. Isotopic evidence for oceanic barium cycling in the initial stage of the Mesoproterozoic. Earth and Planetary Science Letters, 658: 119314.

  85.Wei, W.*,Wang, H.*, Zhang, S., Dong, L.-H., Li, D., Huang, F., 2025. Dynamic redox evolution in the middle-late Mesoproterozoic oceans. Chemical Geology, 679:122685.

2024

  84.Wang, H., Zhang, S.*, Wang, X., Su, J., Ye, Y., Liu, Y., 2024. A novel model of the carbon cycle in the Cambrian ocean. Science China Earth Sciences, 67(6): 1759-1778.

  83.王华建, 付秀丽, 2024. 松辽古大湖地宫寻宝. 石油知识, 5: 13-15.

  82.Wang, H., Wan, Y., Liu, Y., Zhang, J., Zhang, S.*, 2024. Proven and potential microbial contributions to the Gulong shale oil. Journal of Earth Science, 35(6): 2149-2153.

  81.王华建*, 柳宇柯, 王晓梅, 刘真吾, 吕丹, 张水昌, 2024. 松辽盆地青山口组页岩有机质的源-汇过程与地质驱动因素. 矿物岩石地球化学通报, 43(2): 306–318.

  80. Zhang, S.*,Wang, H., Wang, X., Zheng, W., Hao, J., Pogge von Strandmann, P.A., Ye, Y., Shi, M., Liu, Y., Lyu, Y., 2024. Subaerial volcanism broke mid-Proterozoic environmental stasis. Science Advances, 10: eadk5991.

  79. Zhang, S.*, Wang, H., Liu, Y., Wang, X., Liu, H., Sun, L.*, 2024. Lacustrine carbon sink: A hidden driver of the Late Cretaceous Cooling Event. Science Bulletin, 69(24): 3949-3958.

  78. Zhang, S.*,Wang, H., Su, J., Wang, X., He, K., Liu, Y., 2024. Control of Earth system evolution on the formation and enrichment of marine ultra-deep petroleum in China. Petroleum Exploration and Development, 51(04): 870-885. 张水昌*,王华建, 苏劲, 王晓梅, 何坤, 柳宇柯, 2024. 地球系统演化对中国海相超深层油气形成与富集的控制作用. 石油勘探与开发, 51(4): 759-773.

  77. Zhu, R.*, Zhang, S., Wang, H., Wang, X., Liu, Y., Zhang, W., Hao, F., Jin, Z., 2024. Multi-spheric interactions driven differential formation and accumulation of hydrocarbon resources in the North Sea Basin. Science China Earth Sciences, 67(11): 3397–3420. 朱日祥*, 张水昌,王华建, 王晓梅, 柳宇柯, 张旺, 郝芳, 金之钧, 2024. 多圈层作用驱动北海盆地油气形成与富集. 中国科学: 地球科学, 54(11): 3433-3457.

  76. Zhu, R.*, Wang, H., Wang, H., Wang, X., Wan, B., Zhang, W., Zhu, H., Liu, Y., Liu, J., Meng, Q., Hao, F., Jin, Z., 2024. Multi-spherical interactions and mechanisms of hydrocarbon enrichment in the Southeast Asian archipelagic tectonic system. Science China Earth Sciences, 67(2): 566-583. 朱日祥*, 王红军,王华建, 王晓梅, 万博, 张旺, 祝厚勤, 柳宇柯, 刘俊来, 孟庆任, 郝芳, 金之钧, 2024. 东南亚多岛海构造体系圈层相互作用与油气富集机理. 中国科学: 地球科学, 54(2): 587-603.

  75. Ye, Y., Wang, X.*,Wang, H., Fan, H., Chen, Z., Guo, Q., Wang, Z., Wu, C., Canfield, D.E.,Zhang, S., 2024. Hydrological dynamics and manganese mineralization in the wake of the Sturtian glaciation. Geochimica Et Cosmochimica Acta, 376: 14-24.

  74. Ye, Y., Wang, X.*,Wang, H., Wu, C., Zhang, S., 2024. Exploring climate variability during the Marinoan glaciation: A study of black shale geochemistry. Gondwana Research, 128: 315-324.

  73. Ye, Y., Wang, X.,Wang, H., Fan, H., Chen, Z., Guo, Q., Wang, Z., Wu, C., Canfield, D.E., Zhang, S.*, 2024. Phosphate oxygen isotopes constrain Mesoproterozoic marine temperatures and the paucity of phosphorite. Chemical Geology, 644: 121831.

  72. Lyu, Y., Wang, X.*,Wang, H., Ma, S., Ye, Y., Yuan, C., Zhang, P., Zhang, S., 2024. A protracted Mesoproterozoic carbon cycle perturbation in response to volcanism at 1.39 Ga. Palaeogeography Palaeoclimatology Palaeoecology, 650.

2023

  71. Liu, Y.,Wang, H.*, Zhang, J.*, Liu, Z., Chen, F., Wang, X., Zhang, S., Liu, H., 2023. Rare earth elemental and Sr isotopic evidence for seawater intrusion event of the Songliao Basin 91 million years ago. Petroleum Science, 20: 1347-1362.

  70. Liu, Z., Liu, Y., Du, X., Lyu, D., Wu, H.*,Wang, H.*, 2023. Early diagenesis in the lacustrine ostracods from the Songliao Basin 91.35 million years ago and its geological implications. Minerals, 13(5): 13010005.

  69. Huangfu, Y., Zhang, J., Zhang, S.*, Wang, X., He, K., Guan, P., Zhang, H., Zhang, B.,Wang, H., 2023. Petroleum Retention, Intraformational Migration and Segmented Accumulation within the Organic-rich Shale in the Cretaceous Qingshankou Formation of the Gulong Sag, Songliao Basin, Northeast China. Acta Geologica Sinica‐English Edition, 97(5): 1568-1586.

  68. Jin, Z.*, Wang, X.,Wang, H., Ye, Y., Zhang, S., 2023. Organic carbon cycling and black shale deposition: An Earth system science perspective. National Science Review, 10: nwad243.

  67. Ye, Y.,Wang, H., Wang, X., Li, J., Wu, C., Zhang, S.*, 2023. Regional and global proxies for varying ocean redox conditions at∼ 1.57 Ga: A causal connection with volcanism-induced weathering. Geosystems and Geoenvironment,2: 100173.

  66. Wang, X., Wu, M., Ma, S., Su, J., He, K.,Wang, H., Zhang, S.* 2023. From cyanobacteria to kerogen: A model of organic carbon burial. Precambrian Research, 390: 107035.

  65. Wang, X., Zhang, S.*, Ye, Y., Ma, S., Su, J.,Wang, H., Canfield, D.E.*, 2023. Nitrogen cycling during the Mesoproterozoic as informed by the 1400 million year old Xiamaling Formation. Earth-Science Reviews, 243: 104499.

  64. Zhang, S.*, Wang, X.,Wang, H., Tang, Q., Zhang, F., Lü, D., 2023. What are the limiting environmental factors for the evolution of early eukaryotic diversity? Journal of Earth Science, 34(4): 1313-1314.

  63.Song, Y.*, Bowyer, F.T., Mills, B.J., Merdith, A.S., Wignall, P.B., Peakall, J., Zhang, S., Wang, X.,Wang, H., Canfield, D.E., 2023. Dynamic redox and nutrient cycling response to climate forcing in the Mesoproterozoic ocean. Nature Communications, 14(1): 6640.

  62. Heard, A.W.*, Wang, Y., Ostrander, C.M., Auro, M., Canfield, D.E., Zhang, S.,Wang, H., Wang, X., Nielsen, S.G., 2023. Coupled vanadium and thallium isotope constraints on Mesoproterozoic ocean Oxygenation around 1.38-1.39 Ga. Earth and Planetary Science Letters, 610: 118127.

  61. Zhu, R.*, Zhang, S., Wan, B., Zhang, W., Li, Y.,Wang, H., Luo, B., Liu, Y., He, Z., Jin, Z., 2023. Effects of Neo-Tethyan evolution on the petroleum system of Persian Gulf Superbasin. Petroleum Exploration and Development, 50(1): 1-13.

  朱日祥*, 张水昌, 万博, 张旺, 李勇,王华建, 罗贝维, 柳宇柯, 何治亮, 金之钧, 2023. 新特提斯域演化对波斯湾超级含油气盆地形成的影响. 石油勘探与开发, 50(1): 1-11.

  60. Zhang, S.*, Zhang, B., Wang, X., Feng, Z., He, K.,Wang, H., Fu, X., Liu, Y., Yang, C., 2023. Gulong shale oil enrichment mechanism and orderly distribution of conventional– unconventional oils in the Cretaceous Qingshankou Formation, the Songliao Basin, NE China. Petroleum Exploration and Development, 50(5): 1045-1059.

  张水昌*, 张斌, 王晓梅, 冯子辉, 何坤,王华建, 付秀丽, 柳宇柯, 杨春龙, 2023. 松辽盆地古龙页岩油富集机制与常规—非常规油有序分布. 石油勘探与开发, 50(5): 911-923.

  59. 吕丹,王华建*, 李罡, 张江永, 付秀丽, 刘畅, 王晓梅, 朱如凯, 张水昌, 2023. 松辽盆地青山口组页岩沉积水体环境演变的古生物学证据. 石油与天然气地质, 44(4): 857-868.

  58. 张天舒, 朱如凯*, 蔡毅,王华建, 吕丹, 周海燕, 付秀丽, 刘畅, 崔坤宁, 张素荣, 王浡, 吴松涛, 张婧雅, 姜晓华, 冯有良, 刘合, 2023. 松辽盆地古龙凹陷白垩系青山口组页岩层序等时格架下的有机质分布规律. 石油与天然气地质, 44(04): 869-886.

  57. 康淑娟*, 仰云峰,王华建, 江文滨, 何坤, 刘冉冉, 2023. 松辽盆地中央坳陷区三肇凹陷上白垩统青山口组一段页岩含油性特征. 石油实验地质, 45(01): 89-98.

2022

  56.Wang, H., Ye, Y., Deng, Y., Wang, X., Hammarlund, E., Fan, H., Canfield, D.E.*, Zhang, S.C.*, 2022. Isotope evidence for the coupled iron and carbon cycles 1.4 billion years ago. Geochemical Perspectives Letters, 21: 1-6.

  55.Wang, H., Su, J., Wang, X., Ye, Y., Wang, Y., Fang, Y., Zhang, S.*, 2022. Carbon isotope stratigraphy of the Cambrian System in the eastern Tarim Basin, China. Acta Geologica Sinica-English Edition, 96(4): 1277-1293.

  54. Lyu, D.#, Deng, Y.#, Wang, X., Ye, Y., Pang, K., Miao, L., Luo, Z., Zhang, F., Lu, Y., Deng, S.,Wang, H.*, Zhang, S., 2022. New chronological and paleontological evidence for Paleoproterozoic eukaryote distribution and stratigraphic correlation between the Yanliao and Xiong’er basins, North China Craton. Precambrian Research, 371: 106577.

  53. Zhang, F.,Wang, H.*, Ye, Y., Liu, Y., Lyu, Y., Deng, Y., Lyu, D., Wang, X., Wu, H., Deng, S., Zhang, S., 2022. Did high temperature rather than low O2 hinder the evolution of eukaryotes in the Precambrian? Precambrian Research, 378: 106755.

  52. Liu, Y., He, W., Zhang, J., Liu, Z., Chen, F.,Wang, H.*, Ye, Y., Lyu, Y., Gao, Z., Yu, Z., Bi, L., Zhang, S., 2022. Multi-element imaging reveals the diagenetic features and varied water redox conditions of a lacustrine dolomite nodule. Geofluids, 2022: 9019061.

  51. Ye, Y.,Wang, H., Wang, X., Wu, C., Canfield, D.E., Zhang, S.*, 2022. Application of Cd as a paleo-environment indicator. Palaeogeography, Palaeoclimatology, Palaeoecology, 585: 110749.

  50. Cai, Y., Zhu, R.*, Luo, Z., Wu, S., Zhang, T., Liu, C., Zhang, J., Wang, Y., Meng, S.,Wang, H., Zhang, Q., 2022. Lithofacies and Source Rock Quality of Organic-Rich Shales in the Cretaceous Qingshankou Formation, Songliao Basin, NE China. Minerals, 12(4): 465.

  49. Zhang, S.*,Wang, H., Wang, X., Ye, Y., 2021. The Mesoproterozoic Oxygenation Event. Science China Earth Sciences, 64(12): 2043-2068. 张水昌*,王华建, 王晓梅, 叶云涛, 2022. 中元古代增氧事件. 中国科学: 地球科学, 52(1): 26-52.

  48. 张水昌*,王华建, 王晓梅, 叶云涛, 2022. 中元古代海洋生物碳泵: 有机质来源、降解与富集. 科学通报, 67(15): 1624-1643.

  47. 张水昌*, 王晓梅,王华建, 唐卿, 张凤廉, 吕丹, 2022. 早期真核生物多样性演化的限制性环境因素是什么?. 地球科学, 47(10): 3856-3857.

2021

  46.Wang, H.*, Ye, Y., Deng, Y., Liu, Y., Lyu, Y., Zhang, F., Wang, X., Zhang, S., 2021. Multi-element imaging of a 1.4 Ga authigenic siderite crystal. Minerals, 11(12): 1395.

  45. Deng, Y.,Wang, H.*, Lyu, D., Zhang, F., Gao, Z., Ren, R., Ye, Y., Lyu, Y., Wang, X., Guan, P., Zhang, S., 2021. Evolution of the 1.8–1.6 Ga Yanliao and Xiong’er basins, North China Craton. Precambrian Research, 365: 106383.

  44. Lyu, D., Deng, Y.,Wang, H.*, Zhang, F., Ren, R., Gao, Z., Zhou, C., Luo, Z., Wang, X., Bi, L., Zhang, S., Canfield, D.E., 2021. Using cyclostratigraphic evidence to define the unconformity caused by the Mesoproterozoic Qinyu Uplift in the North China Craton. Journal of Asian Earth Sciences, 206: 104608.

  43. Zhang, F.,Wang, H.*, Ye, Y., Deng, Y., Lyu, Y., Wang, X., Yu, Z., Lyu, D., Lu, Y., Zhou, C., Bi, L., Deng, S., Zhang, S., Canfield, D.E., 2021. The environmental context of carbonaceous compressions and implications for organism preservation 1.40 Ga and 0.63 Ga. Palaeogeography, Palaeoclimatology, Palaeoecology, 573: 110449.

  42. Ye, Y.,Wang, H.*, Wang, X., Zhai, L., Wu, C., Zhang, S., 2021. In situ rare earth element analysis of a lower Cambrian phosphate nodule by LA-ICP-MS. Geological Magazine, 158(4): 749-758.

  41. Zhang, S.*, Su, J., Ma, S.,Wang, H., Wang, X., He, K., Wang, H., Canfield, D.E., 2021. Eukaryotic red and green algae populated the tropical ocean 1400 million years ago. Precambrian Research, 357: 106166.

  40. Canfield, D.E.*, van Zuilen, M.A., Nabhan, S., Bjerrum, C.J., Zhang, S.,Wang, H., Wang, X., 2021. Petrographic carbon in ancient sediments constrains Proterozoic Era atmospheric oxygen levels. Proceedings of the National Academy of Sciences of the United States of America, 118(23): e2101544118.

  39. Wang, X., Ye, Y., Wang, H., Zhang, S.*, 2021. Decoupled Cr, Mo, and U records of the Hongshuizhuang Formation, North China: Constraints on the Mesoproterozoic ocean redox. Marine and Petroleum Geology, 132: 105243.

  38. Wang, X., Zhang, S.*, Ye, Y., He, K., Su, J., Huang, L., Fang, Y.,Wang, H., Canfield, D.E., 2021. Molecular and carbon isotopic evidence of pigments indicating a dynamic oceanic chemocline 1.4 billion years ago in northern China. Organic Geochemistry, 154: 104207.

  37. Liu, Y., Zhang, S.*, Zou, C., Wang, X., Sokolov, I., Su, J.,Wang, H., He, K., 2021. Quantitative measurement of interaction strength between kaolinite and different oil fractions via atomic force microscopy: Implications for clay-controlled oil mobility. Marine and Petroleum Geology, 133: 105296.

  36. Fang, Y., Huang, L.*, Shuai, Y., Zhang, B., Nie, H., Li, J., Wei, C.,Wang, H., Zhang, W., 2021. A post-synthesis modification method of molecular sieve 13X for enriching hopanoids in petroleum. Petroleum Research, 6(3): 257-263.

  35. 张凤廉,王华建*, 张水昌, 邓胜徽, 叶云涛, 邓焱, 王晓梅, 吕丹, 卢远征, 吕怡潼, 2021. 元古宙真核藻类演化及环境控制因素. 地质学报, 95(05): 1334-1355.

  34. 高志勇*,王华建, 冯佳睿, 罗忠, 张宇航, 李晓红, 2021. 燕辽海盆中元古界下马岭组沉积期的物源性质与古地理环境. 地质学报, 95: 3606-3628.

  33. 付勇*, 周文喜,王华建, 谯文浪, 叶云涛, 江冉, 王晓梅, 苏劲, 李迪, 夏鹏, 2021. 黔北下寒武统黑色岩系的沉积环境与地球化学响应. 地质学报, 95(02): 536-548.

  32. 王晓梅, 张水昌*, 何坤,王华建, 米敬奎, 苏劲, 叶云涛, 2021. 最小含氧带和硫化环境控制14亿年前有机质生烃能力. 科学通报, 66(23): 3005-3017.

2020

  31.Wang, H.*, Zhao, W., Cai, Y., Wang, X., Ye, Y., Su, J., He, K., Zhang, W., Huang, L., Zhang, S., 2020. Oil generation from the immature organic matter after artificial neutron irradiation. Energy & Fuels, 34(2): 1276-1287.

  30.Wang, H.*, Zhao, W., Cai, Y., Ye, Y., Wang, X., Bi, L., Zhang, S., 2020. Irradiation caused gas generation from organic matter: evidence from the neutron irradiation experiment. IOP Conference Series: Earth and Environmental Science, 569(1): 012090.

  29.Wang, H.*, Zhang, S., Wang, X., Zhang, B., Bian, L., Bi, L., 2020. Hydrocarbon generation from bacterial biomass in ca. 1320 million years ago. IOP Conference Series: Earth and Environmental Science, 600(1): 012032.

  28. Ye, Y.,Wang, H., Wang, X., Zhai, L., Wu, C., Canfield, D.E., Zhang, S.*, 2020. Tracking the evolution of seawater Mo isotopes through the Ediacaran–Cambrian transition. Precambrian Research, 350: 105929

  27. Ye, Y.,Wang, H., Wang, X., Zhai, L., Wu, C., Zhang, S.*, 2020. Elemental geochemistry of lower Cambrian phosphate nodules in Guizhou Province, South China: an integrated study by LA-ICP-MS mapping and solution ICP-MS. Palaeogeography, Palaeoclimatology, Palaeoecology, 538: 109459.

  26. Canfield, D.E.*, Bjerrum, C.J., Zhang, S.,Wang, H., Wang, X., 2020. The modern phosphorus cycle informs interpretations of Mesoproterozoic Era phosphorus dynamics. Earth-Science Reviews, 208: 103267.

  25. Cheng, D., Zhang, S.*, Zhang, Z., Zhou, C.,Wang, H., Yuan, X., Chen, X., 2020. An astronomically calibrated stratigraphy of the Mesoproterozoic Hongshuizhuang Formation, North China: Implications for pre-Phanerozoic changes in Milankovitch orbital parameters. Journal of Asian Earth Sciences, 199: 104408.

2019

  24. Zhang, S., Wang, X.,Wang, H., Bjerrum, C., Hammarlund, E.U., Haxen, E.R., Wen, H., Ye, Y., Canfield, D.E.*, 2019. Paleoenvironmental proxies and what the Xiamaling Formation tells us about the mid‐Proterozoic ocean. Geobiology, 17(3): 225-246.

  23. Luo, P., Zhong, N.*, Khan, I., Wang, X.,Wang, H., Luo, Q., Guo, Z., 2019. Effects of pore structure and wettability on methane adsorption capacity of mud rock: Insights from mixture of organic matter and clay minerals. Fuel, 251: 551-561.

  22.Zhao, W., Wang, X.*, Hu, S., Zhang, S.,Wang, H., Guan, S., Ye, Y., Ren, R., Wang, T., 2019. Hydrocarbon generation characteristics and exploration prospects of Proterozoic source rocks in China. Science China Earth Sciences, 62(6): 909-934. 赵文智, 王晓梅*, 胡素云, 张水昌,王华建, 管树巍, 叶云涛, 任荣, 王铜山, 2019. 中国元古宇烃源岩成烃特征及勘探前景. 中国科学: 地球科学, 49(6): 939-964.

  21. 竺成林,王华建*, 叶云涛, 王晓梅, 黄家旋, 朱玉梅, 杨瑞东, 2019. 基于原位多元素成像分析龙马溪组笔石成因及地质意义. 岩矿测试, 038(003): 245-259.

  20. 罗情勇, 郝婧玥, 李可文, 徐耀辉, 王晓梅,王华建, 栾进华, 胡科, 李甜, 钟宁宁*, 2019. 下古生界有机质成熟度评价新参数:笔石表皮体光学特征再研究. 地质学报, 93(09): 2362-2371.

  19. 谭聪, 卢远征, 宋昊南, 吕奇奇, 邓胜徽*,王华建, 苏玲, 2019. 华北克拉通西南缘高山河组凝灰岩锆石U-Pb年龄及其地质意义. 地质学报, 93(05): 1113-1124.

2018

  18. Canfield, D.E.*, Zhang, S.,Wang, H., Wang, X., Zhao, W., Su, J., Bjerrum, C., Haxen, E., Hammarlund, E.U., 2018. A Mesoproterozoic Iron Formation. Proceedings of the National Academy of Sciences of the United States of America, 115(17): E3895-E3904.

  17. Canfield, D.E.*, Zhang, S., Frank, A.B., Wang, X.,Wang, H., Su, J., Ye, Y., Frei, R., 2018. Highly fractionated chromium isotopes in Mesoproterozoic-aged shales and atmospheric oxygen. Nature Communications, 9(1): 2871.

  16. Wang, X., Zhao, W., Zhang, S.*,Wang, H., Su, J., Canfield, D.E., Hammarlund, E.U., 2018. The aerobic diagenesis of Mesoproterozoic organic matter. Scientific Reports, 8: 13324.

  15. Ye, Y.,Wang, H., Zhai, L., Wang, X., Wu, C., Zhang, S.*, 2018. Contrasting Mo–U enrichments of the basal Datangpo Formation in South China: Implications for the Cryogenian interglacial ocean redox. Precambrian Research, 315: 66-74.

2017

  14. Zhang, S.*, Wang, X.,Wang, H., Hammarlund, E.U., Su, J., Wang, Y., Canfield, D.E., 2017. The oxic degradation of sedimentary organic matter 1400 Ma constrains atmospheric oxygen levels. Biogeosciences, 14(8): 2133-2149.

  13. Wang, X., Zhang, S.,Wang, H., Bjerrum, C.J., Hammarlund, E.U., Haxen, E.R., Su, J., Wang, Y., Canfield, D.E.*, 2017. Oxygen, climate and the chemical evolution of a 1400 million year old tropical marine setting. American Journal of Science, 317(8): 861-900.

  12. Wang, X., Zhang, S.*,Wang, H., Canfield, D.E., Su, J., Hammarlund, E.U., Bian, L., 2017. Remarkable Preservation of Microfossils and Biofilms in Mesoproterozoic Silicified Bitumen Concretions from Northern China. Geofluids, 2017: ID 4818207.

  11. Wang, X., Zhang, S.*,Wang, H., Su, J., He, K., Wang, Y., Wang, X., 2017. Significance of source rock heterogeneities: A case study of Mesoproterozoic Xiamaling Formation shale in North China. Petroleum Exploration & Development, 44(1): 32-39. 王晓梅, 张水昌*,王华建, 苏劲, 何坤, 王宇, 王晓琦, 2017. 烃源岩非均质性及其意义——以中国元古界下马岭组页岩为例. 石油勘探与开发, 44(1): 32-39.

  10. 周文喜,王华建*, 付勇, 叶云涛, 王晓梅, 苏劲, 王富良, 葛枝华, 梁厚鹏, 魏帅超, 2017. 基于LA-ICP-MS多元素成像技术的早寒武世磷结核成因研究. 岩矿测试, 36(02): 97-106.

  9. 叶云涛,王华建, 翟俪娜, 周文喜, 王晓梅, 张水昌, 吴朝东*, 2017. 新元古代重大地质事件及其与生物演化的耦合关系. 沉积学报, 35(02): 203-216.

  8. 蔡郁文*,王华建, 王晓梅, 何坤, 张水昌, 吴朝东, 2017. 铀在海相烃源岩中富集的条件及主控因素. 地球科学进展, 32(02): 199-208.

  7. 蔡郁文*, 张水昌, 何坤, 米敬奎, 张文龙, 王晓梅,王华建, 吴朝东, 2017. 磁铁矿对有机质生烃及同位素分馏的影响. 天然气地球科学, 28(02): 331-340.

  6. 蔡郁文, 张水昌*, 何坤, 米敬奎, 张文龙, 王晓梅,王华建, 吴朝东, 2017. 烃源岩中无机矿物对有机质生烃的影响. 石油实验地质, 39(02): 253-260.

2016

  5.Wang, H.*, Zhang, S., Ye, Y., Wang, X., Zhou, W., Su, J., 2016. In situ imaging of multi-elements on pyrite using laser ablation-inductively coupled plasma-mass spectrometry. Chinese Journal of Analytical Chemistry, 44(11): 1665-1670.

  4. Zhang, S.*, Wang, X.,Wang, H., Bjerrum, C.J., Hammarlund, E.U., Costa, M.M., Connelly, J.N., Zhang, B., Su, J., Canfield, D.E.*, 2016. Sufficient oxygen for animal respiration 1,400 million years ago. Proceedings of the National Academy of Sciences of the United States of America, 113(7): 1731-1736.

  3. Zhang, S.*, Wang, X.,Wang, H., Bjerrum, C.J., Hammarlund, E.U., Dahl, T.W., Canfield, D.E., 2016. Reply to Planavsky et al.: Strong evidence for high atmospheric oxygen levels 1,400 million years ago. Proceedings of the National Academy of Sciences of the United States of America, 113(9): E2552-E2553.

  2. Su, J., Zhang, S.*, Huang, H., Wang, Y.,Wang, H., He, K., Wang, X., Zhang, B., Wang, H., 2016. New insights into the formation mechanism of high hydrogen sulfide–bearing gas condensates: case study of Lower Ordovician dolomite reservoirs in the Tazhong uplift, Tarim Basin. AAPG Bulletin, 100(6): 893-916.

2015

  1. Zhang, S., Wang, X., Hammarlund, E.U.,Wang, H., Costa, M.M., Bjerrum, C.J., Connelly, J.N., Zhang, B., Bian, L., Canfield, D.E.*, 2015. Orbital forcing of climate 1.4 billion years ago. Proceedings of the National Academy of Sciences of the United States of America, 112(12): E1406-E1413.

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