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Abstract
Introduction
Protocol
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환경과학

原位含甲烷沉积物中自黄铁矿的制备及应用模拟器硫同位素分析

Published: August 31, 2017
doi:
10.3791/55970
, , , , , , ,
1School of Earth Sciences and Engineering,Sun Yat-sen University, 2School of Marine Sciences,Sun Yat-sen University, 3Guangdong Provincial Key Laboratory of Marine Resources and Coastal Engineering, 4South China Sea Bio-Resource Exploitation and Utilization Collaborative Innovation Center, 5Institut für Geologie,Universität Hamburg, 6Institut für Geologie und Paläontologie,Westfälische Wilhelms-Universität Münster, 7Guangzhou Marine Geological Survey

Summary

含甲烷沉积物中黄铁矿的硫同位素组成 (δ34) 的分析通常集中在散装样品上。在这里, 我们应用二次离子质谱分析了不同黄铁矿世代的δ34值, 以了解黄的成岩史。

Abstract

自黄铁矿的不同硫同位素组成通常是由硫酸盐驱动的甲烷厌氧氧化 (如此4-AOM) 和 organiclastic 硫酸盐还原 (OSR) 在海洋沉积物中产生的。然而, 由于不同顺序形成的黄铁矿相共存, 解开复杂的黄序列是一个挑战。这份手稿描述了一个样品制备过程, 使使用二次离子质谱 (西姆斯) 获得原位δ34S 值的各种黄铁矿世代。这使得研究人员能够约束如何使4-AOM 影响黄在含甲烷的沉积物中的含量。西姆斯分析揭示了δ34值中的一个极端范围, 从-41.6 到 + 114.8‰, 这比从相同样本的传统的块状硫同位素分析得到的δ34值范围宽得多。浅层沉积物中的黄铁矿主要由34贫化莓, 表明 OSR 早成岩形成。更深的沉积, 更多的黄铁矿发生 overgrowths 和自晶体, 其中显示更高的西姆斯δ34的值比莓。这样的34富硫黄铁矿与 AOM 在硫酸盐-甲烷过渡带, postdating OSR 的增强, 因此,4。高分辨率原位模拟程序硫同位素分析允许黄过程的重建, 这是不能通过散装硫同位素分析来解决的。

Introduction

沉积物中的甲烷排放在大陆边上是常见的1,2。然而, 扩散渗流区的大部分甲烷是在沉积物中以硫酸盐为代价而氧化的, 这一过程被称为4-AOM (方程式 1)3,4。在这一过程中, 硫化物的产生通常导致黄铁矿的沉淀。此外, OSR 还通过释放硫化物 (方程式 2)5来驱动黄铁矿的形成。

CH4 +42- → HS + 小贩3 + H2O (1)

2CH2O + 42- → H2S + 2HCO3 (2)

研究发现, 硫酸盐-甲烷过渡区 (SMTZ) 中的自硫化物揭示了高δ34的值, 这被认为是由增强引起的, 所以4-AOM 在渗透区域的范围内6,7, 8。相比之下, 由 OSR 诱导的黄铁矿通常显示较低δ349。然而, 这是挑战, 以确定不同的硫铁矿世代诱导的这些过程 (即, OSR, 因此4-AOM), 如果只使用一个散装硫同位素测量, 因为连续地形成了贯硫铁矿世代具有不同的同位素组成。因此, 需要进行微量的原位硫同位素分析, 以提高我们对实际矿化过程的认识10,11,12。作为一种多用途的技术为原位同位素分析, 西姆斯只需要几个微克的样本, 这引发了它的指定作为一种无损技术。一个主离子束地目标, 导致二次离子的发射, 随后被传送到质谱仪测量13。在早期的原位硫同位素分析应用中, Pimminger et al.通过使用 10-30 µm 直径光束14成功地分析了在方铅矿中的δ34值。这种方法已越来越多地应用于硫化物中硫同位素的微量分析, 在测量精度和分辨率方面都有显著的改进11,12,13,14,15,16,17,18,19,20. 从渗漏和 non-seep 环境中报告了各种形态属性和不同硫稳定同位素形态的黄铁矿, 从渗、下、21222324。然而, 我们最好的知识, 在我们最近的模拟人生研究6之前, 只有一项研究使用了原位从渗流环境中黄铁矿的硫同位素分析, 揭示了生物黄铁矿的大硫同位素变化25

在这项研究中, 我们应用模拟人分析了自黄铁矿不同世代的δ34值从南海的渗流场, 它允许对 OSR 的微尺度判别-, 因此, 因此,4-AOM 衍生黄铁矿。

Protocol

1. 从沉积物核心收集样品 注: 核心 HS148 是从2006年在南海的沪地区的天然气水合物钻探区的一个地点获得的, 这是在 Sihao 的海洋航行中. 将活塞核心 (此处, HS148) 从顶部到底部 (在船上) 的间隔0.7 米处切割成节, 然后将这些部分转移到冷室 (4 和 #176; C), 以便在检索后进行存储. 将核心部分转移到在陆上实验室中的冷室 (4 和 #176; C), 以便在巡航后存放。把这些?…

Representative Results

数据表达-大块硫磺同位素: 与维也纳峡谷暗黑硫 (V-CDT) 标准相比较, 其体积硫同位素比值表示, 分析精度优于±0.3‰。用国际参考材料对硫同位素测量进行了标定: IAEA-S1 (δ34s =-0.30‰), IAEA-S2 (δ34s =-21.55‰), IAEA-S3 (δ34s =-31.4‰), 和国家统计局 127 (δ34s = 20.30‰)。 <img alt="Equation" src="/files/ftp_upload/55970…

Discussion

硫铁矿的硫同位素分析是一种有用的方法, 可以帮助确定影响黄的生物地球化学过程。然而, 如果采用大容量硫同位素分析, 得到的硫同位素特征通常代表混合信号, 因为沉积黄铁矿聚集物通常是由多贯世代组成的。在这里, 我们提出了一个方法 (即,模拟人分析), 以分析原位硫同位素组成的各种黄铁矿世代的微观尺度。本协议中的关键步骤包括: (1) 从不同的沉积深度 (例如,莓、ove…

Disclosures

The authors have nothing to disclose.

Acknowledgements

这项研究由中国自然科学基金 (No. 91128101、41273054和 41373007) 共同出资和资助, 中国南海天然气水合物资源勘查地质调查项目 (No。DD20160211), 中央大学基础研究基金 (No. 16lgjc11), 广东省高校珠江学者资助计划 (No. 2011)。张志勇林承认中国奖学金委员会 (No. 201506380046) 提供的财政支持。扬路感谢广州精英项目 (No。JY201223) 和中国博士后科学基金 (No. 2016M592565)。我们感谢 Dr. 盛雄杨、Guangxue 和 Dr. 强对广州海洋地质调查所提供的样品和宝贵的建议。我们感谢中国科学院地质与地球物理研究所 (北京) 的 Dr. 华和 Dr., 对模拟人生的分析提供帮助。Dr. 小萍被感谢提供了中国科学院广州地球化学研究所的模拟实验室, 为这篇文章的拍摄做准备。这份手稿得益于 Dr. 艾丽莎 Dsouza 的评论, 《朱庇特》的评论编辑, 以及两位匿名的裁判。

Materials

secondary ion mass spectroscopy Cameca  IMS-1280
 thermal field emission scanning electron microscopy Quanta Quanta 400F
elemental analyser – isotope ratio mass spectrometry ThermoFinnigan ThermoFinnigan Delta Plus
binocular microscope any NA
reflected light microscope Carl Zeiss 3519001617
polishing machicine Struers 60210535
cutting machicine Struers 50110202
carbon/gold coating machicine any NA
ethanol any NA
acetic acid  any NA
zinc acetate solution (3%)    any NA
HCl solution (25%) any NA
1 M CrCl2 solution any NA
0.1 M AgNO3 solution any NA
V2O5 powder any NA
pure nitrogen any NA
syringe any NA
filter(<0.45 µm) any NA
tin cups any NA
round bottom flasks any NA
epoxy Struers 41000004
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References

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Tags

PyriteAuthigenic PyriteMethane-bearing SedimentsIn Situ Sulfur Isotope AnalysisSIMSDiagenetic HistoryBiogeochemical ProcessesOrganiclastic Sulfur ReductionSulfur-driven Anaerobic Oxidation Of MethaneHigh-resolutionPrecisionSediment CoreSediment SeparationPyrite AggregateBulk Sulfur ExtractionMorphological FeaturesTextural FeaturesSample Preparation

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Lin, Z., Sun, X., Peckmann, J., Lu, Y., Strauss, H., Xu, L., Lu, H., Teichert, B. M. Preparation of Authigenic Pyrite from Methane-bearing Sediments for In Situ Sulfur Isotope Analysis Using SIMS. J. Vis. Exp. (126), e55970, doi:10.3791/55970 (2017).
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