OALib Journal期刊
ISSN: 2333-9721
费用：99美元

投递稿件

查看量	下载量

相关文章
更多...

华东政法大学学报 2015

西太平洋富钴结壳中钙质超微化石和分子化石研究

Pulyaeva I A,卢冰,张海生,赵庆英,陈荣华

Keywords: 晚白垩纪西太平洋富钴结壳钙质超微化石分子化石碳同位素

Full-Text Cite this paper Add to My Lib

Abstract:

本文对西太平洋麦哲伦海山CM3D06富钴结壳进行了钙质超微化石生物地层学研究,发现结壳中有代表白垩纪(晚期)、古新世(晚期)、始新世(早、中、晚期)、中新世(中期)、上新世(晚期)和更新世等各时代的标准钙质超微化石,表明结壳的形成始于白垩纪(晚期);在富钴结壳中检出正构烷烃、类异戊二烯烃、甾烷类等众多分子化石,分子化石组合特征指数、主峰碳、ΣC23-/C24+、CPI 、Pr/Ph、Pr/nC17、Ph/nC18和nC31/nC17显示有机质生物母源主要为海洋浮游植物、浮游动物和底栖非光合作用的菌类,而甾烷类的C29、C28和C27含量分布的变化则说明生物种群具有快速演变的特征.此外,还探讨了CM3D06结壳中Pr/Ph和有机碳同位素组成变化与结壳生长过程中的海洋环境演化的关联程度

References

[1]	Summons R E,Jahnke L L,Hope J M,et al. 2-Methylhopanoids as biomarkers for cyanobacterial oxygenic photosynthesis[J]. Nature,1999,400:554-557.
[2]	武光海. 中太平洋海山富钴结壳的特征及其形成环境[D].杭州: 浙江大学,2001. Wu Guanghai. Formation and characteristics for cobalt-rich ferromanganese crusts from the central Pacific seamounts[D]. Hangzhou: Zhejiang University,2001.
[3]	苏新,马维林,程振波.中太平洋海山区富钴结壳的钙质超微化石地层学研究[J]. 地球科学:中国地质大学学报,2004,29(2):141-147. Su Xin,Ma Weilin,Cheng Zhenbo. Calcareous nannofossil biostratigaphy for Co-rich ferromanganese crusts from the central Pacific seamounts[J]. Earth Science: Journal of China University of Geosciences,2004,29(2):141-147.
[4]	张静,于涛,潘家华,等. 西北太平洋中部海山区富钴结壳中的钙质超微化石[J]. 微体古生物学报,2007,24(1): 61-75. Zhang Jing,Yu Tao,Pan Jiahua,et al. Calcareous nannofossil from Cobalt-rich crust in middle Pacific seamount[J]. Acta Micropalaeontologica Sinica,2007,24(1): 61-75.
[5]	潘家华,张静,刘淑琴,等. 西北太平洋富钴结壳的钙质超微化石地层学研究及意义[J]. 地球学报,2007,28(5): 411-417. Pan Jiahua,Zhang Jing,Liu Shuqin,et al. Calcareous nannofossil biostratigraphy of Co-rich crust from northwestern Pacific and its significance[J]. Acta Geoscientica Sinica,2007,28(5): 411-417.
[6]	谢树成,梁斌,郭建秋,等. 生物标志化合物与相关的全球变化[J].第四纪研究,2003,23(5):521-528. Xie Shucheng,Liang Bin,Guo Jianqiu,et al. Biomarkers and the related global change[J].Quaternary Sciences,2003,23(5):521-528.
[7]	谢树成,王志远,王红梅,等. 末次间冰期以来黄土高原的草原植被景观:来自分子化石的证据[J].中国科学(D辑),2002,32(1):28-35. Xie Shucheng,Wang Zhiyuan,Wang Hongmei,et al.Plateau grassland vegetation landscape since the last interglacial loess : evidence from molecular fossils[J].Science in China(Series D),2002,32(1):28-35.
[8]	Roth P H. Calcareousnannofossils-Leg17,Deep Sea Drilling Project[R]//Initial Reports of the Deep Sea Drilling Project.Vol.17. Washington: U S GovtPrinting Office,1973:695-795.
[9]	Edwards A R,Perch-Nielsen K. Calcareous nannofossils from the southwest Pacific,Deep Sea Drilling Project,Leg 29[R]//InitialReports of the Deep Sea Drilling Project,1975.
[10]	Perclr-Nielsen K.Mesozoic calcareous nannofossils[M]//Plankton Stratigraphy.Cambridge:Cambridge University Press,1985:329-426.
[11]	Martini E. Standard Tertiary and Quaternary calcareous nannoplanktonzonation[G]//Farinacct A. Proc 2nd Planktonic Conf. Planktonic MicrofassilsRoma:EdTecnosci.1971: 739-785.
[12]	Okada H,Bukry D. Supplementary modification and introduction of code numbers to the low latitude coccolithbiostratigraphic zonation[J]. Marine Micropaleotology,1980,5:321-325.
[13]	Gartner S. Nannofossils and biostraphy: an overview[J]. Earth-Science Reviews,1977,13:227-250.
[14]	Martini E,Worsley T. Standard Neogene calcareous nannoplankton zonation[J]. Nature,1970,225:289-290.
[15]	Martini E,Worsley T. Tertiary calcareous nannoplankton from the western equatorial Pacific[R]// Init Rep DSDP,Vol.7. Washington:USGoct Printing Office,1971:1471-1507.
[16]	Bukry D. Coocolith stratigraphy,eastern equatorial Pacific,Leg.16,Deep Sea Drilling Project[R]//Init Rep DSSP,Vol.16.Washinggton:USGovt Printing Office,1973:653-711.
[17]	Bukry D.Pytoplankton stratigraphy,Deep Sea Drilling Project,Leg 20,western Pacific Ocean[R]//Init Rep DSDP,Vol.16.Washington:USGovt Printing Office,1973:307-317.
[18]	Bukry D. Biostratigraphy of Cenozoic marine sediment by calcareous nannofossils[J]. Micropaleontology,1978,24:44-60.
[19]	Shumenko S I. Ecology[M]//Proctical Guide to Microfauna of the UUSSR,Vol. 1: CalcareousNannofossils (Nedra,leningrad).1987:11-15.
[20]	刘怀宝,Watkins D K.北美西部内陆海盆Niobrara 组的钙质超微化石及其环境意义Ⅱ[J].高校地质学报,2004,10(1):26-38. Liu Huaibao,Watkins D K. Calcareous Nannofossils from the Niobrara Formation (Upper Cretaceous) and Paleoenvironments of the North American Western Interior Basin Part Ⅱ:Paleoenvironment Study[J]. Geological Journal of China Universities,2004,10(1): 26-38.
[21]	C巴克. 石油勘探中的有机地球化学[M].北京: 石油工业出版社,1982. Barker C. Organic Geochemistry in Petroleum Exploration[M]. Beijing: China Petroleum Industry Press,1982.
[22]	杨群.古生物学领域的新辟园地——分子古生物研究[J]. 古生物学报,1995,34(3): 265-276. Yang Qun. A frontal area in paleonotology: Molecular fossil studies[J]. Acta Paleontologica Sinica,1995,34(3):265-276.
[23]	Shaw P M,Johns R B. The identification of organic input sources of sediments from the Santa Catalina Basin using factor analysis[J]. Organic Geochemistry,1986,10: 951-958.
[24]	Volkman J K,Farrington J W,Gagosian R B. Marine and terrigenous lipids in coastal sediments from the Peru upwelling region at 15°S: sterols and triterpene alcohols[J]. Organic Geochemistry,1987,11:463-477.
[25]	Volkman J K. A review of sterol markers for marme and temgenous matter[J].Organic Geochemisty,1986,9:83-99.
[26]	Bush A B G. Numerical simulation of the Gretaceous Tethys circumglobal current[J]. Science,1997,271:807-810.
[27]	Hotinski R M,Toggweiler J R. Impact of a Tethyancircumglobal passage on ocean heat transport and "equable" climates[J].Paleoceanography,2003,18:1007.
[28]	Zachos J C,Lohmann K C,Walker J C G,et al. Abrupt climate change and transient climates during the Paleogene: Amarinepespective[J]. Journal of Geology,1993,101:191-213.
[29]	Douglas R G,SavinM. Oxygen and carbonisotope analysis of Cretaceous and Tertiaryforaminiferafrom the central north Pacific[R]//Initial Reports of the Deep Sea Drilling Project,Volume 17: Washington (U.S. Government Printing Office).1973:591-605.
[30]	James Z,MarkP,Lisa S,et al. Trend,rhythms,and aberrations in global climate 65 Ma to present[J]. Science,2001,292: 686-693.
[31]	Grantham P J,Wakefiled I I. Variations in the sterane carbon number distributiona of marine source rock derived crude oils through geologicaltime[J]. Organic Geochemistry,1988,12(2):61-73.
[32]	Deines P. The isotopic composition of reduced organic carbon[C]//Handbook of Environmental Isotopic Geochemistry. Amsterdam:Elsevier,1980:320-406.
[33]	Salomons W,Mook W G. Field observationa of the isotopic composition of particulate organic carbon in the Southern North Sea and adjacent estuaries[J]. Marine Geology,1981,41:11-20.
[34]	Fry B,Sherr E B. δ13C measurements as indicators of carbon flow in marine and freshwater ecosystems[J]. Contributions to Marine Science,1984,27:13-47.
[35]	Hunt J M. The significance of carbon isotope variations in marine sediments[M]//Advances in Organic Geochemistry. Oxford: Pergamon,1970:27-35.
[36]	Goad L J,Goodwin T W. The biosynthesis of plant sterols[J].Progress in Phytochemistry,1972,3: 113-198.
[37]	Rieley G,Collier R J,Jones D M,et al. The biogeochemistry of Ellesmere Lake,U. K. -I:source correlation of leaf wax inputs to sedimentary lipid record[J].Organic Geochemistry,1991,17:901-912.
[38]	David K R,James C Z,Robert M O,et al. Global change at the Paleocene-Eocene boundary: climates and evolutionary consequences of tectonic events[J]. Palaegeography,Palaegeography,Palaegeography,1990(79): 117-128.
[39]	Wang C S,Hu X M,Janasa L,et al. Upper Cretaceous oceanic red beds in southern Tibet: Amajor change from anoxic to oxic condition[J]. Cretaceous Research,2005,26:21-32.

Full-Text

Contact Us

service@oalib.com

QQ:3279437679

WhatsApp +8615387084133