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碳酸盐岩烃源岩不同热模拟方式下气体碳同位素演变特征

陈磊 郑伦举 黄海平 宁传祥

陈磊, 郑伦举, 黄海平, 宁传祥. 碳酸盐岩烃源岩不同热模拟方式下气体碳同位素演变特征[J]. 石油实验地质, 2022, 44(1): 121-128. doi: 10.11781/sysydz202201121
引用本文: 陈磊, 郑伦举, 黄海平, 宁传祥. 碳酸盐岩烃源岩不同热模拟方式下气体碳同位素演变特征[J]. 石油实验地质, 2022, 44(1): 121-128. doi: 10.11781/sysydz202201121
CHEN Lei, ZHENG Lunju, HUANG Haiping, NING Chuanxiang. Carbon isotopic evolution of hydrocarbon gases generated from carbonate source rocks via different thermal simulation methods[J]. PETROLEUM GEOLOGY & EXPERIMENT, 2022, 44(1): 121-128. doi: 10.11781/sysydz202201121
Citation: CHEN Lei, ZHENG Lunju, HUANG Haiping, NING Chuanxiang. Carbon isotopic evolution of hydrocarbon gases generated from carbonate source rocks via different thermal simulation methods[J]. PETROLEUM GEOLOGY & EXPERIMENT, 2022, 44(1): 121-128. doi: 10.11781/sysydz202201121

碳酸盐岩烃源岩不同热模拟方式下气体碳同位素演变特征

doi: 10.11781/sysydz202201121
基金项目: 

国家自然科学基金 42072156

国家自然科学基金企业创新发展联合基金 U19B6003

详细信息
    作者简介:

    陈磊(1993-), 男, 硕士研究生, 从事油气地球化学研究。E-mail: 1291521919@qq.com

    通讯作者:

    郑伦举(1966-), 男, 博士, 研究员, 从事油气地球化学与非常规油气地质等相关研究。E-mail: 292002418@qq.com

  • 中图分类号: TE122.113

Carbon isotopic evolution of hydrocarbon gases generated from carbonate source rocks via different thermal simulation methods

  • 摘要: 我国海相烃源岩普遍处于高—过成熟阶段,现有的烃气碳同位素指标不能直接应用于判识海相碳酸盐岩天然气成因类型以及进行油气源对比。利用云南禄劝Ⅱ1型低成熟海相碳酸盐岩烃源岩,开展了不同热模拟方式下的系列热解生烃实验,对收集的气体产物进行碳同位素分析。结果表明:①在整个热演化阶段,干酪根碳同位素值随成熟度变化不大,而甲、乙烷碳同位素值均随成熟度增加先变轻再变重,具有相似的演变特征,在油气生成的主要阶段,明显小于其母质干酪根碳同位素值,在过成熟阶段,乙烷碳同位素变重的趋势明显加快,甚至大于其母质干酪根的碳同位素值,呈现出“煤型气”特征,故单纯地采用甲、乙烷碳同位素值来判识天然气类型时需要慎重;②在成熟度相同时,半封闭—半开放体系模拟实验所得气体碳同位素值相比封闭体系模拟实验的要轻,这指示同一烃源岩排出烃气所形成的常规天然气藏,其烃气碳同位素值与滞留在源内的页岩气碳同位素值存在一定的差异,显示出似乎“不同源”的特征,在利用碳同位素模版或回归公式开展气源对比时也需要注意;③两种热模拟方式下、同一种烃源岩在全演化阶段,甲烷碳同位素值总是比乙烷的要小,这表明由单一烃源岩直接供气形成的常规天然气藏,不会发生甲、乙烷碳同位素的“倒转现象”。

     

  • 图  1  云南禄劝泥盆系华宁组海相碳酸盐岩烃源岩碳同位素随成熟度的演变特征

    样品DK-LQ-2为半封闭—半开放体系实验;其他样品为封闭体系实验。

    Figure  1.  Evolution of carbon isotopes with maturity of marine carbonate source rocks in Devonian Huaning Formation, Luquan area, Yunnan province

    图  2  云南禄劝泥盆系华宁组海相碳酸盐岩2种热模拟方式下甲烷、乙烷碳同位素演变特征对比

    DK-LQ-2为半封闭—半开放体系实验;LQ-2为封闭体系实验。

    Figure  2.  Comparison of carbon isotopic evolution of methane and ethane with two thermal modeling methods in marine carbonate rocks of Devonian Huaning Formation, Luquan area, Yunnan province

    图  3  云南禄劝泥盆系华宁组海相碳酸盐岩烃源岩不同演化阶段热模拟天然气δ13C1δ13C2的关系

    底图来源于文献[30]。

    Figure  3.  Relationship between δ13C1 and δ13C2 values of thermally simulated natural gas in different evolution stages of marine carbonate source rocks in Devonian Huaning Formation, Luquan area, Yunnan province

    图  4  云南禄劝海相碳酸盐岩烃源岩不同热模拟演化阶段天然气δ13C2δ13C2δ13C1的关系

    底图据戴金星等[6]修改。

    Figure  4.  Relationship between δ13C2 and δ13C2-δ13C1 of natural gas in different thermal simulation stages of marine carbonate source rocks in Devonian Huaning Formation, Luquan area, Yunnan province

    表  1  云南禄劝泥盆系华宁组泥灰岩基本油气地球化学特征

    Table  1.   Basic geochemical characteristics of marl in Devonian Huaning Formation, Luquan area, Yunnan province

    样品编号 ω(TOC)/% VRo/% 沥青“A”/% IH/(mg·g-1) 碳酸盐矿物/% 显微组分/% 类型指数 干酪根类型
    腐泥组 壳质组 镜质组 惰质组
    LQ-2 3.45 0.58 0.145 2 425 40.04 78 12 4 6 75 1
    LQ-4 4.55 0.58 0.204 7 429 35.95 74 15 6 5 75 1
    LQ-5-2 5.33 0.58 0.278 6 356 33.15 72 16 5 7 75 1
    下载: 导出CSV

    表  2  云南禄劝泥盆系华宁组海相泥灰岩生烃模拟实验条件

    Table  2.   Simulation experiment conditions for hydrocarbon generation in marine marl in Devonian Huaning Formation, Luquan area, Yunnan province

    序号 模拟温度/℃ 恒温时间/h 上覆静岩压力/MPa 流体压力/MPa 等效镜质体反射率/%
    DK-LQ-2 LQ-2 LQ-4 DK-LQ-2 LQ-2 LQ-4 LQ-5-2 DK-LQ-2 LQ-2 LQ-4 LQ-5-2
    1 250 48 3.5 2.8 3.2 0.62 0.61 0.65
    2 300 48 94 48.8 5.8 6.2 6.9 0.71 0.78 0.75 0.78
    3 350 48 108 56.3 10.2 11.4 12.3 1.05 1.12 1.18 1.15
    4 400 48 121 63.1 23.5 24.6 26.8 1.57 1.68 1.66 1.70
    5 450 48 139 72.5 26.4 28.6 29.2 1.96 2.25 2.11 2.17
    6 500 48 163 85.0 32.2 35.1 35.9 2.79 2.75 2.67 2.71
    7 550 48 173 90.0 3.22
    注:DK-LQ-2为半封闭—半开放体系实验;其他样品为封闭体系实验。
    下载: 导出CSV

    表  3  云南禄劝泥盆系华宁组泥灰岩在不同热模拟方式下干酪根和气体碳同位素值

    Table  3.   Carbon isotopic values of kerogen and gas generated from marl in Devonian Huaning Formation, Luquan area, Yunnan province with different thermal modeling methods

    热模拟方式 样品号 模拟温度/℃ δ13CPDB/‰ 碳同位素差值/‰
    干酪根 甲烷 乙烷 丙烷 Δδ13CPDB(干酪根-甲烷) Δδ13CPDB(乙烷-甲烷)
    封闭体系 LQ-2 -32.55
    LQ-2 250 -32.72 -42.14 -36.32 -34.40 9.42 5.82
    LQ-2 300 -32.61 -43.66 -38.4 -36.33 11.05 5.26
    LQ-2 350 -32.53 -45.11 -37.60 -35.96 12.59 7.51
    LQ-2 400 -32.35 -44.40 -36.59 -34.19 11.65 7.81
    LQ-2 450 -32.17 -40.96 -34.03 -26.65 8.79 6.93
    LQ-2 500 -32.38 -38.15 -26.32 5.77 11.83
    半封闭—半开放体系 DK-LQ-2 300 -32.25 -40.41 -36.84 -36.17 8.16 3.57
    DK-LQ-2 350 -32.43 -47.92 -39.30 -36.56 15.49 8.62
    DK-LQ-2 400 -32.78 -47.10 -37.57 -34.91 14.32 9.53
    DK-LQ-2 450 -32.36 -45.10 -36.42 -34.2 12.74 8.68
    DK-LQ-2 500 -31.74 -41.44 -31.65 -22.36 9.70 9.79
    DK-LQ-2 550 -31.93 -38.63 -23.97 -20.53 6.70 14.66
    封闭体系 LQ-4 -32.96
    LQ-4 250 -32.64 -41.44 -37.52 -35.18 0.89 3.92
    LQ-4 300 -32.89 -42.18 -38.09 -36.53 9.29 4.09
    LQ-4 350 -32.8 -45.95 -37.56 -36.10 13.15 8.39
    LQ-4 400 -32.75 -45.36 -36.49 -34.73 12.61 8.87
    LQ-4 450 -32.21 -41.72 -33.62 -26.30 9.51 8.10
    LQ-4 500 -32.66 -38.54 -26.41 5.88 12.13
    LQ-5-2 -33.28
    LQ-5-2 250 -33.40 -40.78 -38.46 -36.53 2.30 2.32
    LQ-5-2 300 -33.40 -41.21 -38.70 -37.21 7.81 2.51
    LQ-5-2 350 -33.19 -46.49 -37.56 -36.06 13.30 8.93
    LQ-5-2 400 -33.2 -45.58 -36.20 -34.27 12.38 9.38
    LQ-5-2 450 -33.07 -41.67 -33.12 -26.20 8.60 8.55
    LQ-5-2 500 -33.11 -38.59 -26.08 5.48 12.51
    注:Δδ13CPDB(干酪根-甲烷)与Δδ13CPDB(乙烷-甲烷)表示括号内两者之间的差值。
    下载: 导出CSV
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出版历程
  • 收稿日期:  2021-02-08
  • 修回日期:  2021-11-29
  • 刊出日期:  2022-01-28

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