真光层海水过饱和甲烷的来源及机制探讨

张亭亭, 梁前勇, 赵静, 肖曦, 董一飞, 郭斌斌, 钟超, 吴学敏, 杨林. 真光层海水过饱和甲烷的来源及机制探讨[J]. 海洋地质与第四纪地质, 2020, 40(1): 50-59. doi: 10.16562/j.cnki.0256-1492.2018083101
引用本文: 张亭亭, 梁前勇, 赵静, 肖曦, 董一飞, 郭斌斌, 钟超, 吴学敏, 杨林. 真光层海水过饱和甲烷的来源及机制探讨[J]. 海洋地质与第四纪地质, 2020, 40(1): 50-59. doi: 10.16562/j.cnki.0256-1492.2018083101
ZHANG Tingting, LIANG Qianyong, ZHAO Jing, XIAO Xi, DONG Yifei, GUO Binbin, ZHONG Chao, WU Xuemin, YANG Lin. Discussion on the sources and mechanism of supersaturated methane in euphotic seawater[J]. Marine Geology & Quaternary Geology, 2020, 40(1): 50-59. doi: 10.16562/j.cnki.0256-1492.2018083101
Citation: ZHANG Tingting, LIANG Qianyong, ZHAO Jing, XIAO Xi, DONG Yifei, GUO Binbin, ZHONG Chao, WU Xuemin, YANG Lin. Discussion on the sources and mechanism of supersaturated methane in euphotic seawater[J]. Marine Geology & Quaternary Geology, 2020, 40(1): 50-59. doi: 10.16562/j.cnki.0256-1492.2018083101

真光层海水过饱和甲烷的来源及机制探讨

  • 基金项目: 南海北部天然气水合物重点区环境调查项目(DD20190218);国家自然科学基金青年基金“海马冷泉甲烷微渗漏范围、幅度及其与水合物稳定带的相互关系”(41806074);国家自然科学基金重点项目“南海北部冷泉和天然气水合物发育区海底浅表层沉积物碳循环数值模拟”(41730528);自然资源部海底矿产资源重点实验室开放基金“海马冷泉区甲烷气体泄露的立体监测体系分析”(KLMMR-2017-A-10);自然资源部海底矿产资源重点实验室开放基金“采薇平顶海山-洋流相互作用及其对沉积动力的潜在影响”(KLMMR-2017-A-02);广州市科技计划项目2018年广东省科技创新战略专项资金任务“南海天然气水合物气源成因:来自热成因烃类微生物降解过程的指示”(201909010002)
详细信息
    作者简介: 张亭亭(1990—),女,助理工程师,主要从事海洋微生物生态学研究,E-mail:Yulanlin126@126.com
    通讯作者: 梁前勇(1983—),男,高级工程师,主要从事天然气水合物环境影响研究,E-mail:tomlqy@163.com
  • 中图分类号: P731

Discussion on the sources and mechanism of supersaturated methane in euphotic seawater

More Information
  • 真光层海水中普遍存在甲烷过饱和现象,尤其是天然气水合物区真光层的甲烷明显异常。由于临近海气界面,真光层过饱和甲烷与大气甲烷排放及全球温室效应密切相关。目前,对真光层海水的过饱和甲烷来源仍没有统一的认识。综合前人研究成果梳理了真光层海水过饱和甲烷的来源,归纳了真光层海水过饱和甲烷现象形成的影响因素,进一步探讨了原位微生物可能参与的甲烷代谢机制。真光层过饱和甲烷可能来源于沉积物、临近河流或原位微生物,且受区域、季节、营养盐等多种因素的影响。由于受氧气影响,真光层海水甲烷产生的代谢机制有其特殊性,目前推测微生物可能依旧利用常规的产甲烷途径,它们存在于海水微厌氧环境中,或自身形成抵抗氧气影响的能力;此外,微生物也可能选择对氧不敏感的新的产甲烷途径。因此,针对天然气水合物区真光层甲烷过饱和现象,开展甲烷的来源和代谢机制的研究,以期为天然气水合物试采与开发的环境评价提供理论支撑,并为探究海水甲烷对大气及全球气候的影响提供理论依据。

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  • 图 1  真光层海水过饱和甲烷可能的来源

    Figure 1. 

    图 2  真光层海水甲烷产生可能存在的代谢途径(据文献[95,10,106]修改)

    Figure 2. 

    表 1  真光层海水甲烷过饱和现象的实例

    Table 1.  Examples of methane supersaturation in euphotic zone of the ocean

    位置海域甲烷分布真光层过饱和甲烷浓度参考文献
    东、黄海春季表层海水中溶解甲烷浓度自沿岸向外海里呈逐渐降低趋势,在长江口外甲烷浓度呈明显的舌状分布黄海表层甲烷春季为3.43±0.23 nM;东海表层甲烷
    春季为3.24±0.59 nM,夏季为12.8±14.0 nM
    [27]
    南海北部从珠江口到外海表层海水甲烷浓度逐渐降低表层甲烷浓度为2.4~5.9 nM,过饱和度达134%~297%[26]
    易北河口及相邻的
    北海
    甲烷分布受河口富甲烷输入和外海贫甲烷稀释的
    共同影响
    海岸附近的甲烷平均浓度为30±13 nM、外海浓度为
    14±6 nM
    [28]
    南海北部陆坡天然气水合物区不同季节,表层海水甲烷浓度变化较大部分季节上层100 m甲烷浓度过饱和,高达20~30 nM[9]
    亚热带北太平洋表层海水甲烷浓度与季节无明显关系表层海水(<300 m)甲烷浓度2~3 nM,
    甲烷通量达到1.6 μmol·m−2·d−1
    [29]
    北极洋大陆架西伯利亚东部海域超过50%水域的表层海水甲烷过饱和表层海水浓度范围是0~200 nM[22]
    波罗的海中部哥特兰盆地东部水域甲烷偏高,受极地水输入的影响东部水域表层海水甲烷浓度与大气甲烷平衡(~3 nM),而浅层海水(20~40 m)浓度达15~77 nM[30]
    极地陆架区域斯图尔峡湾表层海水和次表层海水的甲烷互不影响水体甲烷浓度范围是5~55 nM[31]
    智利中部大陆架甲烷浓度可能受风力驱动的沿海上升流影响表层海水(0~30 m)甲烷饱和度为125%~550%
    (O2饱和度>100%)
    [32]
    弗拉姆海峡西部区域寡营养的北部极地水输入,甲烷浓度偏高水体浅表层(<20 m)表层甲烷浓度范围是6~9 nM[7]
    黑海研究区域位于冷泉区,甲烷浓度随深度逐渐升高近表层甲烷浓度约为5 nM[5]
    波罗的海表层海水盐度偏低,从底层到表层溶解甲烷浓度
    呈梯度下降
    表层甲烷浓度约为4 nM[6]
    下载: 导出CSV

    表 2  存活于有氧环境下产甲烷古菌类群

    Table 2.  The surviving methanogenic archaeal communities in oxic environments

    产甲烷古菌类型产甲烷古菌类群参考文献
    氢营养型Methanomicrobiales(目)Methanogenium(科)[49, 54]
    Methanobacteriales(目)Methanobacterium(属), Methanobrevibacter(属)[49, 59]
    Methanocellales(目)Methanocella(属)[50-51, 54]
    乙酸营养型Methanosarcinales(目)Methanosaeta/Methanothrix(种)[52, 54]
    Methanosarcina(属)[50-51, 54]
    甲基营养型Methanosarcinales(目)Methanosarcinaceae(科)[54, 56]
    Methanosarcinales(目)Methanomicrococcus blatticola(种)[60]
    下载: 导出CSV
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出版历程
收稿日期:  2018-08-31
修回日期:  2019-03-21
刊出日期:  2020-02-25

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