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长江口−东海内陆架早期成岩过程及影响因素

汲雨 赵彬 李康 韩露露 陈霖 姚鹏

汲雨,赵彬,李康,等. 长江口−东海内陆架早期成岩过程及影响因素[J]. 海洋学报,2023,45(8):73–85 doi: 10.12284/hyxb2023127
引用本文: 汲雨,赵彬,李康,等. 长江口−东海内陆架早期成岩过程及影响因素[J]. 海洋学报,2023,45(8):73–85 doi: 10.12284/hyxb2023127
Ji Yu,Zhao Bin,Li Kang, et al. Early diagenetic processes and influencing factors of the Changjiang River Estuary and East China Sea inner-shelf[J]. Haiyang Xuebao,2023, 45(8):73–85 doi: 10.12284/hyxb2023127
Citation: Ji Yu,Zhao Bin,Li Kang, et al. Early diagenetic processes and influencing factors of the Changjiang River Estuary and East China Sea inner-shelf[J]. Haiyang Xuebao,2023, 45(8):73–85 doi: 10.12284/hyxb2023127

长江口−东海内陆架早期成岩过程及影响因素

doi: 10.12284/hyxb2023127
基金项目: 国家自然科学基金(42076034,42006041)
详细信息
    作者简介:

    汲雨(1997-),女,山东省菏泽市人,主要从事海洋有机生物地球化学研究。E-mail:425613278@qq.com

    通讯作者:

    姚鹏(1977-),男,山东省菏泽市人,教授,主要从事海洋有机生物地球化学研究。E-mail:yaopeng@ouc.edu.cn

  • 中图分类号: P736.21+3

Early diagenetic processes and influencing factors of the Changjiang River Estuary and East China Sea inner-shelf

  • 摘要: 边缘海沉积物中的早期成岩作用是影响碳循环和埋藏的重要过程,目前对早期成岩过程及其影响因素的了解还不够深入。于2018年8月在长江口−东海内陆架采集了短柱状沉积物,对间隙水中溶解无机碳(DIC)、溶解无机氮(DIN)、二价铁(${\rm{Fe}}^{2+}$)、二价锰(${\rm{ Mn}}^{2+}$)和硫酸根(${\rm{SO}}^{2-}_4$)离子等参数进行了分析,并结合表层沉积物中粒度、比表面积、有机碳及稳定碳同位素组成和底层水环境参数,研究了不同沉积环境下沉积物中的早期成岩过程及其影响因素。结果表明,长江口−东海内陆架泥质区沉积物间隙水中DIC和${{\rm {NH}}_4^+} $的浓度随着深度的增加逐渐增大,且在其中心站位有较高的DIC、${{\rm {NH}}_4^+} $产生通量(分别为4.03 mmol/(m2·d)和0.57 mmol/(m2·d))和${{\rm {SO}}_4^{2-}} $消耗通量(−4.56 mmol/(m2·d)),沉积物扰动深度为20~40 cm,自长江口向浙闽沿岸逐渐降低;而在砂质区,各溶质在剖面上均无明显变化,且通量较小(DIC: 0.60 mmol/(m2·d);${{\rm {NH}}_4^+} $:−0.03 mmol/(m2·d);${{\rm {SO}}_4^{2-}} $:−1.05 mmol/(m2·d)),沉积物不存在扰动。扰动层厚度与沉积物间隙水中DIC和${{\rm {NH}}_4^+} $等溶质通量呈正相关,表明沉积物的物理扰动是影响泥质区沉积有机碳再矿化的重要因素。综合上述结果,发现沉积有机碳在泥质区扰动层的降解方式以铁锰还原作用为主,扰动层以下以硫酸盐还原作用为主,而在砂质区的降解主要靠耗氧呼吸作用。本研究丰富了长江口及邻近海域沉积动力过程对早期成岩作用影响的认识,有助于深入理解大河河口及邻近海域有机碳的循环和埋藏。
  • 图  1  长江口−东海内陆架及邻近海域采样站位点信息(橙黄色色块代表东部边缘海泥质区)

    Fig.  1  Information of sampling stations in the Changjiang River Estuary and East China Sea inner-shelf (the orange color block represents the mud area of the eastern marginal sea)

    图  2  长江口−东海内陆架沉积物间隙水中 DIC(a−e),$ {{\rm {NH}}_4^+} $(a−e),$ {{\rm {SO}}_4^{2-}} $(a−e),${\rm{NO}}_3^-$(f−j),$ {{\rm {NO}}_2^-}$(f−j),Fe2+(k−o)和Mn2+(k−o)的浓度剖面

    图中虚线为扰动层和非扰动层的分界线

    Fig.  2  Concentration profile of DIC (a−e), $ {{\rm {NH}}_4^+} $ (a−e), $ {{\rm {SO}}_4^{2-}} $ (a−e), ${{\rm {NO}}_3^-}$ (f−j), $ {{\rm {NO}}_2^-} $ (f−j), Fe2+ (k−o) and Mn2+ (k−o) in sediment porewater of the Changjiang River Estuary and East China Sea inner-shelf

    The dotted line in the figure is the boundary between the reworked layer and the unreworked layer

    图  3  长江口−东海内陆架沉积物间隙水中DIC(a)、$ {{\rm {NH}}_4^+} $(b)、${{\rm {SO}}_4^{2-}} $(c)的通量分布

    图中红色站位为本研究站位,灰色站位重新计算于参考文献[19]

    Fig.  3  Fluxes distribution of DIC (a), $ {{\rm {NH}}_4^+} $ (b) and ${{\rm {SO}}_4^{2-}} $ (c) in sediment porewater of the Changjiang RiverEstuary and East China Sea inner-shelf

    The red station in the figure is the station of this study, and the gray station is recalculated in the reference [19]

    图  4  长江口−东海内陆架基本理化参数对DIC、$ {{\rm {NH}}_4^+} $${{\rm {SO}}_4^{2-}} $ 通量的 RDA

    Fig.  4  RDA of DIC, $ {{\rm {NH}}_4^+} $ and ${{\rm {SO}}_4^{2-}} $ fluxes from basic physical and chemical parameters in the Changjiang River Estuary and East China Sea inner-shelf

    图  5  长江口−东海内陆架沉积物间隙水扰动层与非扰动层中${{\rm {NH}}_4^+} $(a)、${{\rm {SO}}_4^{2-}} $(b)浓度与DIC浓度的关系

    Fig.  5  Relationship between concentrations of ${{\rm {NH}}_4^+} $ (a), ${{\rm {SO}}_4^{2-}} $ (b) and DIC in the reworked and unreworked layers of sediment porewater in the Changjiang River Estuary and East China Sea inner-shelf

    图  6  长江口−东海内陆架沉积物间隙水扰动层厚度与 DIC(a)、$ {{\rm {NH}}_4^+} $(b)、${{\rm {SO}}_4^{2-}} $(c)通量的关系以及 δ13C 与 ${{\rm {SO}}_4^{2-}} $ 通量(d)的关系

    Fig.  6  The relationship between the thickness of sediment porewater reworked layer and DIC (a), $ {{\rm {NH}}_4^+} $ (b) and ${{\rm {SO}}_4^{2-}} $ (c) fluxes and relationship between δ13C and ${{\rm {SO}}_4^{2-}} $ fluxes (d) in the Changjiang River Estuary and East China Sea inner-shelf

    表  1  长江口−东海内陆架底层水和表层沉积物的基本理化参数

    Tab.  1  Basic physical and chemical parameters of bottom water and surface sediment in the Changjiang River Estuary and East China Sea inner-shelf

    站位水深/m底层水温/°C底层水盐度底层DO含量/(mg·L−1TOC含量/%δ13C值/‰孔隙度SSA/(m2·g−1中值粒径/μm(TOC/SSA) /(mg·m−2
    A6−313.725.428.05.180.69−22.960.8116.637.30.41
    C218.327.329.46.750.68−22.860.7017.337.30.39
    F226.425.234.01.580.54−22.230.7615.798.90.34
    H226.226.434.13.140.61−22.090.7316.686.60.37
    A6−747.021.130.13.190.29−21.750.593.901020.74
    下载: 导出CSV

    表  2  长江口−东海内陆架沉积物间隙水中溶质的产生/消耗通量(正值代表产生,负值代表消耗)

    Tab.  2  Production/consumption fluxes of solute in sediment porewater of the Changjiang River Estuary and East China Sea inner-shelf (positive value represents generation, negative value represents consumption)

    站位 产生/消耗通量/(mmol·m−2·d−1
    DIC$ {{\rm {NH}}_4^+} $$ {{\rm {SO}}_4^{2-}} $Fe2+Mn2+
    A6−34.030.57−4.560.01−0.03
    C20.740.14−1.140.02−0.01
    F23.230.29−2.190−0.01
    H20.450.06−1.0400
    A6−70.60−0.03−1.0500
    下载: 导出CSV

    表  3  世界典型河口和海洋环境沉积物间隙水中 DIC、$\bf{{ {NH}}_4^+}$${\bf{{{{SO}}_4^{2-}} }}$的产生和消耗通量(单位:mmol/(m2·d))

    Tab.  3  Fluxes of DIC, $ {{\bf {NH}}_4^+}$, ${{\bf {SO}}_4^{2-}}$ in sediment porewater of typical estuaries and marine environment sediments in the world (unit: mmol/(m2·d) )

    区域DIC$ {{\rm {NH}}_4^+} $${{\rm {SO}}_4^{2-}} $使用方法参考文献
    长江口0.45~4.030.03~0.57−1.04~−4.56PROFILE模型本研究
    长江口0.08~7.590.02~0.54−0.03~−10.86PROFILE模型文献[19](重新计算)
    黄河口2.18~16.550.01~1.37−12.91~−31.64PROFILE模型文献[46]
    东海泥质区2.94~11.70.56~2.78−5.78~−16.2沉积物培养实验文献[19]
    南黄海泥质区2.36~3.130.42~0.62−2.26~−2.60沉积物培养实验文献[19]
    巴布亚新几内亚湾10~42沉积物培养实验文献[47]
    亚马孙−圭亚那移动泥带19~127沉积物培养实验文献[9]
    亚马孙河口1.79~42.570.03~2.94沉积物培养实验文献[48]
    法属圭亚那20~235沉积物培养实验文献[12]
    刚果河口1.13~4.080.11~0.37Fick第一定律文献[49]
    波罗的海深水0.01~3.330~0.38Fick第一定律文献[50]
    波罗的海2.3~43.5沉积物培养实验文献[51]
    格但斯克盆地0.29~2.95Fick第一定律文献[52]
    格但斯克盆地0.21~3.43沉积物培养实验文献[52]
    墨西哥湾3.4~820~7.2沉积物培养实验文献[53]
    毛里塔尼亚5.64~20.06沉积物培养实验文献[54]
    新斯科舍浅海14.74~151.53−4.07~9.24沉积物培养实验文献[55]
    亚得里亚海0.50~8.760.04~1.62Fick第一定律文献[56]
    亚得里亚海2.2~1730.16~1.61沉积物培养实验文献[56]
    新不列颠海沟0.10~0.60Fick第一定律文献[57]
    拉普捷夫海0.08~0.19稳态下的一般反应−输运方程文献[58]
    阿鲁海0.6~38.40.01~4.2沉积物培养实验文献[59]
    注:“−”代表未检测。
    下载: 导出CSV
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  • 收稿日期:  2022-12-04
  • 修回日期:  2023-03-14
  • 网络出版日期:  2023-04-28
  • 刊出日期:  2023-08-31

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