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基于CDOM光谱特征的泥页岩产气特征评价

郑晓璇 田继先 田聪 蒋峥文 杨磊 贺秋芳 薛红蕾

郑晓璇, 田继先, 田聪, 蒋峥文, 杨磊, 贺秋芳, 薛红蕾. 基于CDOM光谱特征的泥页岩产气特征评价[J]. 地质科技通报, 2024, 43(4): 128-140. doi: 10.19509/j.cnki.dzkq.tb20230652
引用本文: 郑晓璇, 田继先, 田聪, 蒋峥文, 杨磊, 贺秋芳, 薛红蕾. 基于CDOM光谱特征的泥页岩产气特征评价[J]. 地质科技通报, 2024, 43(4): 128-140. doi: 10.19509/j.cnki.dzkq.tb20230652
ZHENG Xiaoxuan, TIAN Jixian, TIAN Cong, JIANG Zhengwen, YANG Lei, HE Qiufang, XUE Honglei. Evaluation of the characteristics of biogenic gas production based on the CDOM spectral characteristics of shales[J]. Bulletin of Geological Science and Technology, 2024, 43(4): 128-140. doi: 10.19509/j.cnki.dzkq.tb20230652
Citation: ZHENG Xiaoxuan, TIAN Jixian, TIAN Cong, JIANG Zhengwen, YANG Lei, HE Qiufang, XUE Honglei. Evaluation of the characteristics of biogenic gas production based on the CDOM spectral characteristics of shales[J]. Bulletin of Geological Science and Technology, 2024, 43(4): 128-140. doi: 10.19509/j.cnki.dzkq.tb20230652

基于CDOM光谱特征的泥页岩产气特征评价

doi: 10.19509/j.cnki.dzkq.tb20230652
基金项目: 

中国石油天然气股份有限公司前瞻性与基础性重大科技项目“不同类型大气田(区)成藏主控因素及邻域评价” 2021DJ0605

详细信息
    作者简介:

    郑晓璇, E-mail: zhengxiaoxuan08@163.com

    通讯作者:

    贺秋芳, E-mail: hqfeddy@swu.edu.cn

  • 中图分类号: P618.13

Evaluation of the characteristics of biogenic gas production based on the CDOM spectral characteristics of shales

More Information
  • 摘要:

    泥页岩中可溶有机质(DOM)组成和可降解性是影响生物气形成的重要因素, 开发简便有效的方法来评估可溶有机质的组成、官能团特征和微生物活性等, 可为泥页岩生物气田产气机制分析提供关键的基础信息。采集了柴达木盆地涩探1井1 219~1 309 m泥质岩心, 基于有色可溶有机质(CDOM)的三维荧光(EEM)和紫外可见吸收光谱特征, 分析了可溶有机质的组分、官能团特征和易降解程度, 了解了产甲烷菌可利用底物的分布情况。结果表明: 涩探1井岩心有机质以易降解的类色氨酸荧光组分C1和C3为主, 占比70.54%;荧光组分、荧光参数HIXBIX和<吸光系数E253/E203SUVA254共同指示1 219~1 222 m和1 285~1 301 m 2个层位有机质腐殖化程度较低, 芳香性较弱, 为潜在的产气活跃层位。研究表明CDOM光谱可以作为分析泥页岩可溶有机质特征的有效方法, 其结果反映了产甲烷菌可利用底物和微生物活性等特征, 为烃源层系内生物产气预测提供有效的重要信息。

     

  • 图 1  柴达木盆地一级构造简图(a)与三湖地区生气区带分布和采样点区位图(b)以及采样位置测井剖面图(c)(a据文献[30]修改)

    Figure 1.  First-order structure diagram (a) of the Qaidam Basin, distribution of gas-bearing zones and location map of sampling sites in the Sanhu area (b) and log profile of sampling location (c)

    图 2  岩心CDOM荧光组分三维荧光图及折半检验

    Figure 2.  EEMs contours of the four fluorescence components identified by PARAFAC

    图 3  岩心CDOM吸收系数光谱图

    Figure 3.  CDOM absorption coefficient spectrogram of the rock core

    图 4  岩心TC、TOC和DOC纵向变化图

    Figure 4.  Systematic variation in the rock core TC, TOC, and DOC contents with depth

    图 5  荧光组分荧光强度、HIXBIXE253/E203SUVA254随深度系统变化

    Figure 5.  Systematic changes in fluorescence component intensity, HIX, BIX, E253/E203 and SUVA254 with depth

    图 6  CDOM荧光组分的相对比例

    Figure 6.  Relative proportions of the four CDOM fluorescence components

    表  1  EEM-PARAFAC解析出4个荧光组分的特征

    Table  1.   Characteristics of the four fluorescence components identified by the EEM-PARAFAC model

    荧光组分 Ex/nm Em/nm 荧光组分类型 文献报道
    Ex/nm Em/nm 参考文献
    C1 <250 366 类色氨酸 C7:240 318 [38]
    C2:240 364 [39]
    C6:240 360 [40]
    C2 260,315 430 类富里酸 C1:250 413 [41]
    C1:335 440 [42]
    C1:270(320) 411 [43]
    C2:260 400 [44]
    C3 280 336 类色氨酸 C3:280 320 [45]
    C2:<280 330 [46]
    C4:280 328 [47]
    C4:275 325 [48]
    C4 345, 425, 265 509 类腐殖酸 C2:365 510 [42]
    C4:<300 498 [49]
    C4:250~450 510 [50]
    注:表中各物理量的含义见正文; Ex为激发波长;Em为发射波长
    下载: 导出CSV

    表  2  紫外可见光吸收光谱和三维荧光光谱参数的指示含义

    Table  2.   Indicators calculated from the ultraviolet visible absorption spectrum and 3D fluorescence EEMs of DOM

    指数 定  义 含  义
    HIX 激发波长254 nm时,发射波长在435~480 nm范围内荧光强度积分值与300~345 nm荧光积分值之比 有机物中腐殖质含量或腐殖化程度高低的指示剂[5]
    BIX 激发波长310 nm时,发射波长在380 nm与430 nm处荧光强度的比值 DOM中内源贡献大小的指标[53]
    E253/E203 253 nm波长与203 nm波长处吸收系数的比值 表征DOM苯环结构上官能团的构成特征[54]
    SUVA254 254 nm处的CDOM吸光度与该样品溶液DOC的浓度之比 表达DOM的芳香性指标[55]
    注:HIX为腐殖化指数;BIX为自生源指数;E253/E203为官能团指数;SUVA254为芳香性指数,下同
    下载: 导出CSV
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  • 收稿日期:  2023-11-24
  • 录用日期:  2024-03-05
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