太平洋海山富钴结壳钙质超微化石生物地层学及生长过程

张海生; 韩正兵; 雷吉江; 赵军; 于培松; 胡佶; 卢冰; PulyaevaI.A.

doi:10.3799/dqkx.2014.073

太平洋海山富钴结壳钙质超微化石生物地层学及生长过程

doi: 10.3799/dqkx.2014.073

张海生^{1, 2,},
韩正兵^{1, 2},
雷吉江²,
赵军^{1, 2},
于培松^{1, 2},
胡佶^{1, 2},
卢冰^{1, 2},
PulyaevaI.A.³

1.
国家海洋局海洋生态系统与生物地球化学重点实验室，浙江杭州 310012
2.
国家海洋局第二海洋研究所，浙江杭州 310012
3.
State Scientific Centre Yuzhmorgeologia, Gelendzhik 353461, Russia

基金项目:

国家自然科学基金 41076072

国家自然科学基金 40676025

详细信息

作者简介:
张海生(1953-)，男，博士，研究员，从事海洋地球化学和古海洋环境研究.E-mail: zhangsoa112355@163.com

中图分类号: P736.4
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出版历程
- 收稿日期: 2013-09-10
- 刊出日期: 2014-07-15

Calcareous Nannofossil Biostratigraphy and Growth Periods of Co-Rich Crusts from Pacific Seamounts

Zhang Haisheng^{1, 2
,},
Han Zhengbing^{1, 2},
Lei Jijiang²,
Zhao Jun^{1, 2},
Yu Peisong^{1, 2},
Hu Ji^{1, 2},
Lu Bing^{1, 2},
Pulyaeva I.A.³

1.
Key Laboratory of Marine Ecosystem and Biogeochemistry, SOA, Hangzhou 310012, China
2.
Second Institute of Oceanography, SOA, Hangzhou 310012, China
3.
State Scientific Centre Yuzhmorgeologia, Gelendzhik 353461, Russia

摘要

摘要: 正确判断富钴结壳生长年代及过程有助于研究结壳形成地质历史和重建古海洋环境.利用生物地层学方法(生物遗留印痕)对太平洋不同海山结壳样品进行生长时代和阶段研究,发现麦哲伦海山CM3D06结壳和中太平洋海山CB14结壳最初形成年代和富集特征差异显著: 前者为白垩纪(或更古老)、晚古新世-早始新世、中-晚始新世、中-晚中新世、上新世-更新世等5个阶段；后者为晚古新世-早始新世、中-晚始新世、中中新世、上新世-更新世等4个阶段.两座海山结壳层内部超微化石组合具有极强的区域性特征，反映了大洋环境对生物的影响以及生物对环境的适应.结壳层间的不整合和结构构造的变化指示在渐新世其生长存在间断期，与成矿作用的间断有关.
- 富钴结壳 /
- 钙质超微化石 /
- 生物地层学 /
- 地质年代 /
- 太平洋海山 /
- 地球化学
Abstract: It enriches the geological history of Co-rich crusts (CRC) formation and the paleoceanography for us to understand the growth ages and periods of CRC. CRC samples collected from the Magellan and mid-Pacific seamounts were studied for the growth geological ages and periods by employing biostratigraphy (biological impressions). The primary formation geological ages and calcareous nannofossil assembly are different between CM3D06 CRC from the Magellan seamount and CB14 CRC from the mid-Pacific seamount. Based on the identification of calcareous nannofossil imprints and original fossil remains,five growth periods are determined for CM3D06 CRC,namely,Cretaceous (or older),Late Paleocene-Early Eocene,Middle-Late Eocene,Middle-Late Miocene,and Pliocene-Pleistocene,whereas four growth periods for CB14 CRC are determined as follows: Late Paleocene,Middle-Late Eocene,Middle Miocene,and Pliocene to Pleistocene. Regional characteristics for the nannofossil combination features of two CRC samples indicate the impact of oceanic environment on marine organisms and their adaptation. The unconformity of sub-layers and variation of structure and texture of the two CRC samples show that the main hiatus occurred during Oligocene.
- Co-rich crust /
- calcareous nannofossil /
- biostratigraphy /
- geological age /
- Pacific seamount /
- geochemistry

HTML全文

图 1 中、西太平洋海山及富钴结壳样品采集站位

1.麦哲伦海山区；2.马尔库斯-威克海山区；3.马绍尔群岛；4.中太平洋海山区；5.莱恩群岛

Fig. 1. Mid and West Pacific seamounts and sampling sites of Co-rich crusts

下载: 全尺寸图片幻灯片

图 2 CM3D06结壳各层年代钙质超微化石(标志化石)的形成时代

钙质超微化石的生物名称对应的长短不一的横线代表该物种的生存阶段；灰色阴影区段代表利用不同物种的年代交集确定的结壳层段的大致生长年龄时段定年方案参考文献(Martini，1971;Bukry, 1973a, 1973b)

Fig. 2. Calcareous nannofossils and geological age in each sub-layer of CM3D06 crust

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图 3 CM3D06结壳中的钙质超微化石分布

Fig. 3. Distribution of calcareous nannofossil species in CM3D06 crust

下载: 全尺寸图片幻灯片

图 4 CB14结壳各层年代钙质超微化石(标志化石)的形成时代

Fig. 4. Calcareous nannofossils and geological age in each sub-layer of CB14 crust

下载: 全尺寸图片幻灯片

图 5 CB14结壳中的钙质超微化石分布

Fig. 5. Distribution of calcareous nannofossil species in CB14 crust

下载: 全尺寸图片幻灯片

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