• 姓名: 田辉
  • 性别: 男
  • 职务: 科技与平台处处长
  • 职称: 研究员
  • 学历: 博士研究生
  • 电话: 020-85290708
  • 传真: 
  • 电子邮件: tianhui@gig.ac.cn
  • 通讯地址: 广州市天河区科华街511号
    简  历:
  •   田辉,男,1977年2月出生,河北保定人。国家杰出青年科学基金(2019)和优秀青年科学基金(2015)获得者,现任广州地球化学研究所科技与平台处处长,有机地球化学国家重点实验室副主任,《Marine and Petroleum Geology》期刊“领域编辑”(Section Editor)。2000年和2003年获中国石油大学(华东)学士和硕士学位;2006年7月毕业于中国科学院广州地球化学研究所,获博士学位。2006年至今,先后任有机地球化学国家重点实验室助理研究员、副研究员和研究员(其中:2014/2–2015/2,美国德克萨斯大学奥斯丁分校访问学者)。主要从事油气地球化学和石油地质学研究,包括深层/深水与非常规油气研究。主要学术成绩包括:(1)利用典型原油样品,厘定了原油裂解气的主生气期与碳同位素特征,建立了原油裂解成气的地质模型,提出了我国原油裂解气成藏的两种模式:原地成藏与异地成藏;(2)针对中国含油气盆地特点,完善了限定体系下原油裂解气与干酪根裂解气的判别图版,指出原油族组成是影响原油裂解气潜力及其地化特征的重要原因之一;(3)揭示了南方下古两套页岩的孔径特征与差异,阐明了超临界甲烷在富微孔页岩上的吸附特征与机理,建立了基于过剩吸附模型的页岩原地气量评价新方法;(4)首次发现了完整系列的C31-C34 25-降苯并霍烷和25-降六氢化苯并霍烷,为研究原油生物降解提供了新指标;首次在川西北P/T界面附近发现了C34 2 -甲基霍烷的异常分布,认为其可能与甲基细菌藿烷多醇侧链的变化及特定沉积环境有关,进而可作为有效的油源对比与古环境恢复指标。上述成果在EPSL、CG、AAPG、OG、MPG等SCI期刊发表50 余篇论文,H-index为24,SCI他引3000余次,3篇第一作者论文入选ESI Top 1%“高被引论文”。

    社会任职:
  •  
    研究方向:
  • 油气地球化学和地质学,包括深层油气和非常规油气。

    科研之友地址:https://www.scholarmate.com/P/rMrMna

    获奖及荣誉:
  •   2022年度广东省自然科学一等奖(R2

    代表论著:
  • 1. Peng Cheng, Hui Tian,* Xianming Xiao, Haifeng Gai, Qin Zhou, Linyuan Zhou, 2023. Influence of Thermal Maturity on the Time-Resolved Emission Spectrum (TRES) Fluorescence Lifetime Characteristics of Crude Oils: A Preliminary Study Based on a Thermal Simulation Experiment of Crude Oils. Energy Fuels 37, 5165?5178.

    2. Zijin Wu, Tengfei Li, Sui Ji, Qin Zhou, Hui Tian*, 2023. Gas Generation from Coal and Coal-Measure Mudstone Source Rocks of the Xujiahe Formation in the Western Sichuan Depression, Sichuan Basin. Journal of Earth Science 34, 1012-1025.

    3. Fugui He, Hui Tian,* Haifeng Gai, Wei Liu, Zheng Qian, Tao Jiang, Qi Han, Jie Fan , Jie Zhang, XiaoXiao Yang, Ao Zhang, 2023. Geochemical characteristics and organic matter enrichment of the lower cretaceous dolomite-rich interval in the Bayindulan sag, Erlian basin, northern China. Geoenergy Science and Engineering 228, 211970.

    4. Yaowen Wu, Hui Tian*, Runsheng Yin, Di Chen, Stephen E. Grasby, Jun Shen, Tengfei Li, Sui Ji, Ping'an Peng, 2023. Highly fractionated Hg isotope evidence for dynamic euxinia in shallow waters of the Mesoproterozoic ocean. Earth and Planetary Science Letters 616, 118211.

    5. Zeyang Liu, Hui Tian*, Runsheng Yin, Di Chen, Haifeng Gai, 2022. Mercury loss and isotope fractionation during thermal maturation of organic-rich mudrocks. Chemical Geology 612, 121144.

    6. Yaowen Wu, Hui Tian*, Zeyang Liu, Shangli Liu, Tengfei Li, Sui Ji, Ping'an Peng, 2022. Interpretation of abnormally negative carbon isotope excursions in Eifelian–Givetian (Middle Devonian) sediments of South China and implications for paleo-environmental variation. Palaeogeography, Palaeoclimatology, Palaeoecology 604, 111225.

    7. Xing Wang, Hui Tian*, Haifeng Gai, Zijin Wu, Qin Zhou, Sui Ji, Tengfei Li, Xianming Xiao, 2022. Generation and geochemical signatures of natural gas from solid bitumen: Implications from closed and stepwise semi-open pyrolysis experiments. Marine and Petroleum Geology 145, 105889.

    8. Zeyang Liu, Hui Tian*, David Selby, Jianfang Hu, D. Jeffrey Over, 2022. Organic geochemistry evidence for wildfire and elevated pO2 at the Frasnian–Famennian boundary. Global and Planetary Change 216, 103904.

    9. Yaowen Wu, Runsheng Yin, Chao Li, Di Chen, Stephen E. Grasby, Tengfei Li, Sui Ji, Hui Tian*, Ping’an Peng, 2022. Global Hg cycle over Ediacaran–Cambrian transition and its implications for environmental and biological evolution. Earth and Planetary Science Letters 587, 117551.

    10. Yaowen Wu, Hui Tian*, Wanglu Jia, Jie, Li, Tengfei Li, Qin Zhou, Luhua Xie, Ping’an Peng2022. Nitrogen isotope evidence for stratified ocean redox structure during late Ediacaran to Cambrian Age 3 in the Yangtze Block of South China. Chemical Geology 589, 120679.

    11. Cheng, P., Liu, B., Tian*, H., Xiao, X., Gai, H., Zhou, Q., Li, T., Liu, D., 2021. Fluorescence lifetime evolution of crude oils during thermal cracking: Implications from pyrolysis experiments in a closed system. Organic Geochemistry 159, 104273.

    12. Wu, Y., Tian*, H., Li, T., Li, Z., Ji, S., Xiao, X., Xie, L., 2021. Enhanced terrestrial organic matter burial in the marine shales of Yangtze platform during the early Carboniferous interglacial interval. Marine and Petroleum Geology 129, 105064.

    13. Wu, Y., Tian*, H., Li, J., Li, T., Ji, S., 2021. Reconstruction of oceanic redox structures during the Ediacaran-Cambrian transition in the Yangtze Block of South China: Implications from Mo isotopes and trace elements. Precambrian Research 359, 106181.

    14. Wang, X., Tian*, H., Zhou, Q., He, C., 2021. Origin and formation of pyrobitumen in Sinian-Cambrian reservoirs of the Anyue gas field in Sichuan Basin: Implications from pyrolysis experiments of different oil fractions. Energy & Fuels 35, 1165-1177.

    15. Wang, X., Tian*, H., Xiao, X., Liu, D., Min, Y., Li, T., Ji, S., Peng, P., 2021. Methane-dominated gaseous inclusions in the Sinian carbonate reservoirs in central Sichuan Basin and their implications for natural gas accumulation. Marine and Petroleum Geology 125, 104871.

    16. Gai, H., Li, T., Wang, X., Tian*, H., Xiao, X., Zhou, Q., 2020. Methane adsorption characteristics of overmature Lower Cambrian shales of deepwater shelf facies in Southwest China. Marine and Petroleum Geology 120, 104565.

    17. Gai, H., Tian*, H., Cheng, P., He, C., Wu, Z., Ji, S., Xiao, X., 2020. Characteristics of molecular nitrogen generation from overmature black shales in South China: Preliminary implications from pyrolysis experiments. Marine and Petroleum Geology 120, 104527.

    18. Wu, Y., Tian*, H., Gong, D., Li, T., Zhou, Q., 2020. Paleo-environmental variation and its control on organic matter enrichment of black shales from shallow shelf to slope regions on the Upper Yangtze Platform during Cambrian Stage 3. Palaeogeography, Palaeoclimatology, Palaeoecology 545, 109653.

    19. Cheng, P., Tian*, H., Xiao, X., Liu, D., Zhang, Y., Huang, B., Zhou, Q., Gai, H., Li, T., 2019. Fluorescence lifetimes of crude oils and oil inclusions: A preliminary study in the Western Pearl River Mouth Basin, South China Sea. Organic Geochemistry 134, 16–31.

    20. Gai, H., Tian*, H., Cheng, P., Zhou, Q., Li, T., Wang, X., Xiao, X., 2019. Influence of retained bitumen in oil-prone shales on the chemical and carbon isotopic compositions of natural gases: Implications from pyrolysis experiments. Marine and Petroleum Geology 101, 148–161.

    21. Gai, H., Tian*, H., Xiao, X., 2018. Late gas generation potential for different types of shale source rocks: Implications from pyrolysis experiments. International Journal of Coal Geology 193, 16–29.

    22. Cheng, P., Tian*, H., Xiao, X., Zhou, Q., Gai, H., Li, T., Wang, X., 2017. Water Distribution in Overmature Organic-Rich Shales: Implications from Water Adsorption Experiments. Energy and Fuels 31, 13120–13132.

    23. Li, T., Tian*, H., Xiao, X., Cheng, P., Zhou, Q., Wei, Q., 2017. Geochemical characterization and methane adsorption capacity of overmature organic-rich Lower Cambrian shales in northeast Guizhou region, Southwest China. Marine and Petroleum Geology 86, 858–873.

    24. Huang, B.J., Zhu, W.L., Tian*, H., Jin, Q., Xiao, X., Hu, C., 2017. Characterization of Eocene lacustrine source rocks and their oils in the Beibuwan Basin, offshore South China Sea. AAPG Bulletin 101, 1395–1423.

    25. Pan, L., Xiao, X.M., Tian*, H., Zhou, Q., Cheng, P., 2016. Geological models of gas in place of the Longmaxi shale in Southeast Chongqing, south China. Marine and Petroleum Geology 73, 433–444.

    26. Huang, B.J., Tian*, H., Li, X., Wang, Z., Xiao, X., 2016. Geochemistry, origin and accumulation of natural gases in the deepwater area of the Qiongdongnan Basin, South China Sea. Marine and Petroleum Geology 72, 254–267.

    27. Tian, H., Li, T., Zhang, T., Xiao, X., 2016. Characterization of methane adsorption on overmature Lower Silurian–Upper Ordovician shales in Sichuan Basin, southwest China: Experimental results and geological implications. International Journal of Coal Geology 156, 36–49.

    28. Huang, B.J., Tian*, H., Huang, H., Yang, J., Xiao, X., Li, L., 2015. Origin and accumulation of CO2 and its natural displacement of oils in the continental margin basins, northern South China Sea. AAPG Bulletin 99, 1349–1369.

    29. Tian, H., Pan, L., Zhang, T., Xiao, X., Meng, Z., Huang, B., 2015. Pore characterization of organic-rich Lower Cambrian shales in Qiannan Depression of Guizhou Province, Southwestern China. Marine and Petroleum Geology 62, 28–43.

    30. Tian, H., Pan, L., Xiao, X.M., Wilkins, R.W.T., Meng, Z.P., Huang, B.J., 2013. A preliminary study on the pore characterization of Lower Silurian black shales in the Chuandong Thrust Fold Belt, Southwestern China using low pressure N2 adsorption and FE-SEM methods. Marine and Petroleum Geology 48, 8–19.

    31. Tian*, H., Cheng, P., Zhou, Q., Xiao, X.M., Wilkins, R.W.T., 2013. Abnormal elevations of C34 2 -methylhopane and C34 2 -methylbenzohopane in a Lower Triassic mudstone sample, NW Sichuan Basin. Organic Geochemistry 63, 139–144.

    32. Huang, B.J, Tian*, H., Wilkins, R.W.T., Xiao, X., Li, L., 2013. Geochemical characteristics, palaeoenvironment and formation model of Eocene organic-rich shales in the Beibuwan Basin, South China Sea. Marine and Petroleum Geology 48, 77–89.

    33. Tian, H., Xiao, X.M., Wilkins, R.W.T., Tang, Y.C., 2012. An experimental comparison of gas generation from three oil fractions: Implications for the chemical and stable carbon isotopic signatures of oil cracking gas. Organic Geochemistry 46, 96–112.

    34. Tian*, H., Cheng, P., Zhou, Q., Xiao, X.M., Wilkins, R.W.T., 2012. A complete series of C31-C34 25-norbenzohopanes in the Devonian and Jurassic bitumen sands, NW Sichuan Basin. Organic Geochemistry 45, 1–6.

    35. Tian, H., Xiao X.M., Wilkins R.W.T., Gan, H., Guo, L., Yang, L., 2010. Genetic origins of marine gases in the Tazhong area of the Tarim basin, NW China: Implications from the pyrolysis of marine kerogens and crude oil. International Journal of Coal Geology 80, 17–26.

    36. Tian, H., Xiao, X.M., Gan, H.J., Yang, L., Guo, L., Shen, J., 2010. A comparative experimental study on gas generation from saturated and aromatic hydrocarbons isolated from a Cambrian oil in Tarim basin. Geochemical Journal 44, 151–158.

    37. Tian, H., Xiao, X.M, Yang, L.G., Xiao, Z., Guo, L., Shen, J., Lu, Y., 2009. Pyrolysis of oil at high temperatures: Gas potentials, chemical and carbon isotopic signatures. Chinese Science Bulletin 54, 1217–1224.

    38. Tian, H., Xiao, X.M., Wilkins, R.W.T., Gan, H., Xiao, Z., Liu D., Guo L., 2008. Formation and evolution of Silurian paleo-oil pools in the Tarim Basin, NW China. Organic Geochemistry 39, 1281–1293.

    39. Tian, H., Xiao, X.M., Wilkins, R.W.T., Tang, Y.C., 2008. New insight into the volume and pressure changes during the thermal cracking of oil to gas in reservoirs: implications for the in-situ accumulation of gas cracked from oils. AAPG Bulletin 92, 181-200.

    40. Tian, H., Xiao, X.M., Wilkins, R.W.T., Li, X.Q., Gan, H.J., 2007. Gas sources of the YN2 gas pool in the Tarim Basin—Evidence from gas generation and methane carbon isotope fractionation kinetics of source rocks and crude oils. Marine and Petroleum Geology 24, 29–41.

    41. Tian, H., Wang, Z.M., Xiao, Z.Y., Li, X.Q., Xiao, X.M., 2006. Oil cracking to gases: Kinetic modeling and geological significance. Chinese Science Bulletin 51, 2763–2770.

    42. 田辉*, 肖贤明,杨立国,肖中尧,郭利果,申家贵,卢玉红,2009. 原油高温裂解生气潜力与气体特征. 科学通报, 54 (6): 781–786.

    43. 田辉*, 肖贤明,李贤庆,肖中尧,申家贵,刘德汉,2007. 海相干酪根与原油裂解气甲烷生成及碳同位素分馏的差异研究. 地球化学, 36(1) : 71–77.

    44. 田辉, 王招明,肖中尧,李贤庆,肖贤明,2006. 原油裂解成气动力学模拟及其意义. 科学通报, 51 (15): 1821–1827.

    45. 伍耀文,龚大建,李腾飞,王星,田辉*2019. 黔中隆起及周缘地区牛蹄塘组含氮页岩气分布特征及有利勘探方向. 地球化学,48(6): 613–623.

    46. 王星,田辉*2018. 页岩中多元气体竞争吸附特征研究现状及展望. 地球化学,47(3): 229–239.

    47. 李敏,田辉*,肖贤明,张水昌,相明辉,盖海峰,程鹏,傅家谟,2014. 塔河油田稠油中25-降苯并藿烷的检出及其意义. 地球化学,43(5): 453–459.

    承担科研项目情况:
  •   1. 国家杰出青年科学基金,41925014,石油与天然气地球化学,2020/01-2024/12;
      2. 基金委重点基金,42330811,鄂西黄陵古隆起周缘海相页岩气形成与富集机制研究,2024/01-2028/12;
      3. 科技部重点研发计划项目,2023YFF0803700,晚奥陶—早志留世全球大规模有机质堆积对地球宜居性的影响,2024/01-2028/12。