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...

中国科学地球科学中国科学地球科学 2013

南海北部神狐海域浅表层沉积物中自生黄铁矿及其泥火山指示意义

, PP. 351-359

谢蕾,王家生,吴能友,邬黛黛,王舟,朱小畏,胡军,陈洪仁,林杞

Keywords: 黄铁矿,分布,硫同位素,浅表层沉积物,神狐海域

Full-Text Cite this paper Add to My Lib

Abstract:

？南海北部神狐海域浅表层沉积物柱状样Site4B中发育异常分布的自生黄铁矿,根据沉积物岩性、结构构造、黄铁矿的硫稳定同位素和TOC含量,发现岩芯柱样约1m深度存在明显的沉积间断界面,自生黄铁矿仅分布在1m以下的沉积物中,主要为棒状和有孔虫填充状,且存在3个异常富集层.黄铁矿含量与沉积物中有机质的含量之间无明显相关性.黄铁矿的硫同位素值δ34S介于-41.69‰～-49.16‰CDT,是硫酸盐还原作用和硫歧化作用的共同产物.研究认为Site4B站位地处南海北部泥火山发育的有利区域构造背景,泥火山作用所带来的深部甲烷等烃类气体影响了沉积物中硫酸盐还原作用的强度和自生黄铁矿形成的数量.深部甲烷等气体含量随泥火山活动的间歇式变化可能导致了岩芯沉积物中自生黄铁矿数量的不均匀分布.

References

[1]	1 张景廉, 张平中. 黄铁矿对有机质成烃的催化作用讨论. 地球科学进展, 1996, 11: 282-287
[2]	2 Rasmussen B. Evidence for pervasive petroleum generation and migration in 3.2 and 2.63 Ga shales. Geology, 2005, 33: 497-500
[3]	3 刘坚, 陆红峰, 廖志良, 等. 东沙海域浅层沉积物硫化物分布特征及其与天然气水合物的关系. 地学前缘, 2005, 12: 258-262
[4]	4 Chen D F, Feng D, Su Z, et al. Pyrite crystallization in seep carbonates at gas vent and hydrate site. Mater Sci Eng C, 2006, 26: 602-605
[5]	5 陈忠, 颜文, 陈木宏, 等. 南沙海槽表层沉积自生石膏-黄铁矿组合的成因及其对天然气渗漏的指示意义. 海洋地质与第四纪地质, 2007, 27: 91-100
[6]	6 蒲晓强, 钟少军, 于雯泉, 等. 南海北部陆坡 NH-1孔沉积物中自生硫化物及其硫同位素对深部甲烷和水合物存在的指示. 科学通报, 2006, 51: 2874-2880
[7]	7 Wignall P B, Newton R. Pyrite framboid diameter as a measure of oxygen deficiency in ancient mudrocks. Amer J Sci, 1998, 298: 537-552
[8]	8 Bond D P G, Wignall P B. Pyrite framboid study of marine Permian-Triassic boundary sections: A complex anoxic event and its relationship to contemporaneous mass extinction. Geol Soc Amer Bull, 2010, 122: 1265-1279
[9]	9 Sassen R, MacDonald I R, Guinasso N L J, et al. Bacterial methane oxidation in sea-floor gas hydrate: Significance to life in extreme environments. Geology, 1998, 26: 851-854
[10]	10 Schieber J. Sedimentary pyrite: A window into the microbial past. Geology, 2002, 30: 531-534
[11]	11 Xiao S H, Schiffbauer J D, McFadden K A, et al. Petrographic and SIMS pyrite sulfur isotope analyses of Ediacaran chert nodules: Implications for microbial processes in pyrite rim formation, silici?cation, and exceptional fossil preservation. Earth Planet Sci Lett, 2010, 297: 481-495
[12]	12 Chambers L A, Trudinger P A. Microbiological fractionation of stable sulfur isotopes: A review and critique. Geomicrobiol J, 1979, 1: 249-293
[13]	13 Berner R A. Early Diagenesis: A Theoretical Approach. Princeton: Princeton University Press, 1980. 1-239
[14]	14 Berner R A. Sedimentary pyrite formation: An update. Geochim Cosmochim Acta, 1984, 48: 605-615
[15]	15 Ohmoto H, Kaiser C J, Geer K A. Systematics of sulphur isotopes in recent marine sediments and ancient sediment-hosted basemetal deposits. In: Herbert H M, Ho S E, eds. Stable Isotopes and Fluid Processes in Mineralisation. Perth: The University of Western Australia Press, 1990. 70-120
[16]	16 Habicht K S, Can?eld D E. Isotope fractionation by sulfate-reducing natural populations and the isotopic composition of sul?de in marine sediments. Geology, 2001, 29: 555-558
[17]	17 常华进, 储雪蕾, 黄晶, 等. 沉积环境细菌作用下的硫同位素分馏. 地质论评, 2007, 53: 807-813
[18]	18 陈芳, 苏新, Nurnberg D, 等. 南海东沙海域末次冰期最盛期以来的沉积特征. 海洋地质与第四纪地质, 2006, 26: 9-17
[19]	19 栾锡武, 彭学超, 邱燕. 南海北部陆坡高速堆积体的构造成因. 现代地质, 2009, 23: 183-198
[20]	20 陆红锋, 刘坚, 陈芳, 等. 东沙海区浅层沉积物中黄铁矿异常及其意义. 南海地质研究, 2007, 1: 48-53
[21]	21 陆红锋, 陈芳, 廖志良, 等. 南海东北部 HD196A岩芯的自生条状黄铁矿. 地质学报, 2007, 81: 519-525
[22]	22 Wu S G, Liu Z, Wang W Y, et al. Late Cenozoic tectonic deformation in the Dongsha Islands and adjacent sea area. Chin J Oceanol Limnol, 2003, 21: 377-388
[23]	23 姚伯初, 万玲, 吴能友, 等. 大南海地区新生代板块构造活动. 中国地质, 2004, 31: 113-122
[24]	24 李前裕, 郑洪波, 钟广法, 等. 南海晚渐新世滑塌沉积指示的地质构造事件. 地球科学, 2005, 30: 19-24
[25]	25 邵磊, 庞雄, 张功成. 南海北部渐新世末的构造事件. 地球科学, 2009, 34: 717-724
[26]	26 黄永样, Erwin S, 吴能友, 等, 著. 南海北部陆坡甲烷和天然气水合物地质—中德合作SO-177航次成果专报. 北京: 地质出版社, 2008. 1-197
[27]	27 苏新, 陈芳, 于兴河, 等. 南海陆坡中新世以来沉积物特性与气体水合物分布初探. 现代地质, 2005, 19: 1-13
[28]	28 吴能友, 张海啟, 杨胜雄, 等. 南海神狐海域天然气水合物成藏系统初探. 天然气工业, 2007, 27: 1-6
[29]	29 孙珍, 庞雄, 钟志洪, 等. 珠江口盆地白云凹陷新生代构造演化动力学. 地学前缘, 2005, 12: 489-498
[30]	30 王家豪, 庞雄, 王存武, 等. 珠江口盆地白云凹陷中央底辟带的发现及识别. 地球科学, 2006, 31: 209-213
[31]	31 石万忠, 宋志峰, 王晓龙, 等. 珠江口盆地白云凹陷底辟构造类型及其成因. 地球科学, 2009, 34: 778-784
[32]	32 吴能友, 杨胜雄, 王宏斌, 等. 南海北部陆坡神狐海域天然气水合物成藏的流体运移体系. 地球物理学报, 2009, 52: 1641-1650
[33]	33 Wang P X, Prell W L, Blum P, et al. Proceedings of Ocean Drilling Program. Initial Reports, Volume 184. Texas A & M, College Station, 2000
[34]	34 陆红锋. 南海东沙海区天然气水合物赋存的沉积证据—沉积物矿物学及地球化学特征研究. 博士学位论文. 广州: 中山大学, 2007. 1-175
[35]	35 Lim Y C, Lin S, Yang T F, et al. Variations of methane induced pyrite formation in the accretionary wedge sediments offshore southwestern Taiwan. Mar Petrol Geol, 2011, 28: 1829-1837
[36]	36 Goldhaber M B, Kaplan I R. Controls and consequences of sulfate reduction rates in recent marine sediments. Soil Sci, 1975, 119: 42-55
[37]	37 Habicht K S, Canfield D E. Sulfur isotope fractionation during bacterial sulfate reduction in organic-rich sediments. Geochim Cosmochim Acta, 1997, 61: 5351-5361
[38]	38 Rees C E, Jenkins W J, Monster J. The sulphur isotopic composition of ocean water sulphate. Geochim Cosmochim Acta, 1978, 42: 377-381
[39]	39 Detmers J, Brüchert V, Habicht K S, et al. Diversity of sulfur isotope fractionations by sulfate-reducing prokaryotes. Appl Environ Microbiol, 2001, 67: 888-894
[40]	40 Canfield D E, Thamdrup B. The production of 34S-depleted sulfide during bacterial disproportionation of elemental sulfur. Science, 1994, 266: 1973-1975
[41]	41 黄华谷, 邸鹏飞, 陈多福. 泥火山的全球分布和研究进展. 矿物岩石地球化学通报, 2011, 30: 189-197
[42]	42 何家雄, 祝有海, 翁荣南, 等. 南海北部边缘盆地泥底辟及泥火山特征及其与油气运聚关系. 地球科学, 2010, 35: 75-86
[43]	43 Milkov A V. Worldwide distribution of submarine mud volcanoes and associated gas hydrates. Mar Geol, 2000, 167: 29-42
[44]	44 王力峰. 晚期泥底辟控制作用导致神狐海域 SH5钻位未获水合物的分析. 现代地质, 2010, 24: 450-456
[45]	45 张美, 孙晓明, 芦阳, 等. 南海台西南盆地自生管状黄铁矿矿物学特征及其对天然气水合物的示踪意义. 矿床地质, 2011, 30: 725-734

Full-Text

Contact Us

service@oalib.com

QQ:3279437679

WhatsApp +8615387084133