贵州喀斯特高原湖泊物质循环过程中的铜锌同位素地球化学－以红枫湖、阿哈湖为例

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	贵州喀斯特高原湖泊物质循环过程中的铜锌同位素地球化学－以红枫湖、阿哈湖为例
其他题名	The Geochemistry of Copper and Zinc Isotopes during Material Cycling of Karstic Plateau Lake in Guizhou Province, China —— A case study of Hongfeng and Aha Lakes near Guiyang City
	梁莉莉
学位类型	博士
	2008-05-23
学位授予单位	中国科学院地球化学研究所
学位授予地点	地球化学研究所
学位名称	博士
关键词	铜同位素锌同位素重金属物质循环示踪生物作用红枫湖阿哈湖
摘要	近年来铜、锌同位素地球化学研究已经进入了快速发展时期。作为新兴的同位素技术手段，铜锌同位素工具已普遍应用于地球化学、矿床学、古海洋学和生物学等多种领域，然而铜、锌同位素在湖泊生态系统中的研究却相对较少。湖泊生态系统中，重金属的迁移、循环与转化一直是地球科学家们关注的焦点，但研究手段仅局限于含量与形态的测定。因此本论文旨在通过对湖泊生态系统中铜、锌同位素的研究，揭示影响铜、锌同位素组成的主要因素，为铜、锌同位素成为湖泊系统中新的重金属示踪工具奠定基础。本论文通过一系列条件实验，确定了用于MC-ICP-MS测定环境样品中铜、锌同位素时最佳的化学分离条件。随后选取红枫湖和阿哈湖为主要研究对象，用此实验流程对湖泊水体及其主要支流悬浮物中的铜、锌同位素的季节及剖面变化进行了初步研究。除此之外，对水体中重金属如Cu、Zn、Mn、Ni、Co、Cr、Cd和Pb的形态分布特征及物质循环进行了研究。主要得出以下几点认识： 1、环境样品中铜锌的最佳分离条件是，采用AG MP-1(100-200目)阴离子交换树脂，分别以7 mol/L HCl + 0.001% H2O2，2 mol/L HCl+ 0.001% H2O2，0.5 mol/L HNO3作为淋洗液，并分别在适当的体积接收淋洗液，可以有效地分离沉积物、植物和悬浮物等样品中的铜和锌。化学分离过程中回收率接近100％，同位素比值的变化均在误差范围以内。 2、红枫湖、阿哈湖水体及主要支流悬浮物和红枫湖生物样品中的δ65Cu分布范围为-2.64‰~1.11‰，可达到3.75‰的变化。红枫湖夏季水体悬浮物的δ65Cu变化为-0.08‰~0.25‰，入湖河流水体悬浮物δ65Cu的变化范围为0.13‰~ 1.11‰；阿哈湖夏季水体悬浮物δ65Cu的变化范围为-0.62‰~0.37‰，入湖河流水体悬浮物δ65Cu的变化范围为-1.08‰~0.60‰。两湖冬季水体悬浮物的δ65Cu值均较负。红枫湖生物样品中δ65Cu较负（-1.54‰~ 0.03‰）。红枫湖水体悬浮物中δ65Cu的随水深的变化趋势主要受到藻类吸收作用的控制，而阿哈湖δ65Cu的随水深的变化趋势主要受到其物源的控制。说明在贫营养化湖泊中，铜同位素组成可以示踪物源；而在富营养化湖泊中，铜同位素组成则可以示踪生物活动。同时水温的垂直变化也可能是其影响因素之一。 3、红枫湖水体及其主要支流水体悬浮物中的δ66Zn变化范围分别为-0.29‰~0.26‰和-0.04‰~0.48‰，阿哈湖水体及其主要支流水体悬浮物中的δ66Zn变化范围分别为-0.18‰~0.27‰和-0.17‰~0.46‰，均表现出支流中的锌同位素组成较重的趋势。而生物样品中的δ66Zn变化范围较大，为-0.35‰~0.57‰。说明湖泊生态系统中各端元的锌同位素组成存在明显差异。红枫湖夏季δ66Zn随着湖水深度的变化，与Chla（叶绿素）呈极显著的正相关(R=0.97)。说明锌同位素组成与藻类生物量有一定的响应关系，主要是藻类对锌的有机吸附或是吸收过程改变了锌同位素组成。阿哈湖的锌同位素组成主要受到其源区的控制作用，从而可利用锌同位素示踪源区；此外，红枫湖和阿哈湖悬浮物中的锌同位素比值均表现出夏季小于冬季，说明大气的干湿沉降可能是一个较负的锌同位素源。生物样品中的δ66Zn变化范围较大，说明由于生物作用过程导致的锌同位素分馏大于非生物过程。 4、红枫湖重金属Mn、Ni、Co、Cr、Cd和Pb的含量在南湖高于北湖，主要是羊昌湖的输入所导致；重金属入湖通量的季节性变化，直接导致了重金属含量的季节性变化。沉积物－水界面在冬夏季节，由于“富氧”和“贫氧”状态的改变，导致了溶解态Mn、Ni和Cr的季节性变化；水粒相互作用过程中，溶解有机碳（DOC）、氧化铁胶体、氧化锰胶体和水生藻类的生长繁殖，影响了重金属不同结合形态的变化。
其他摘要	During the last recent years, the isotopic geochemistry of copper and zinc has experienced a rapid development. As new isotopic tools, copper and zinc isotopes have been widely applied to different aspects of geochemistry like ore deposit, paleoceanography and biology, nevertheless the study of copper and zinc isotopes in lacustrine ecosystem remains poor. In lacustrine environments, for many years, the transport, transformation and cycle of heavy metal have retained the attention of geoscientist，but these researches are mainly confined to the determination of the concentration and speciation of heavy metal. To fill this gap, distribution of copper and zinc isotopes in lake were investigated in this dissertation and the factors controlling copper and zinc isotopes composition were discussed in the aim to establish the base for copper and zinc isotope geochemistry for tracing heavy metal in lacustrine ecosystems. The optimal separation conditions of copper and zinc from environment samples (sediment, plant and suspended particulate material) are studied throμgh a series of experiments. Thereafter, the Hongfeng Lake and Aha Lake were chosen as study area, profile characteristics and seasonal variation of copper and zinc isotopes of the SPM (suspended particulate material) in the two lakes and their main branches were studied. Moreover, the speciation and cycle of heavy metal such as Cu, Zn, Mn, Ni, Co, Cr, Cd and Pb were studied. Several conclusions can be drawn from this thesis and are summarized here: 1. The optimal separation condition of Cu and Zn from environmental samples are described here. AG MP-1 resin (100-200 mesh) was used as anion exchange resin and 7 mol/L HCl + 0.001% H2O2, 2 mol/L HCl+ 0.001% H2O2, 0.5 mol/L HNO3 were used as eluants, and then the fitted volume of eluants were collected respectively. This procedure can effectively separate Cu and Zn from sediments, plants, and suspended particulate matter (SPM) samples with a recovery yield close to 100% that minimizes the isotopic fractionation during the chemical separation enoμgh to be neglected. 2. The variations of Cu isotopic composition of SPM and biological material in Hongfeng Lake, Aha Lake and their main branches range over 3.75‰ from -2.64‰ to 1.11‰。The δ65Cu of SPM in Hongfeng Lake range from -0.08‰ to 0.25‰, and the δ65Cu of SPM in its main branches range from 0.13‰ to 1.11‰ in summer while the δ65Cu of SPM in Aha Lake range from -0.62‰ to 0.37‰, and the δ65Cu of SPM in its main branches range from -1.08‰ to 0.60‰ in summer. For the two lakes, the copper isotope composition of SPM in winter is lighter than in summer. Furthermore, the copper isotope composition in biological material is much lighter and ranges from -1.54‰ to 0.03‰. The profile characteristic of δ65Cu of SPM in Hongfeng Lake is ascribed to absorption by algae in summer, while the copper isotope composition in Aha Lake is mainly controlled by the water inputs from the catchment. These results sμggests that δ65Cu can be used as a good tracer of source materials in oligotrophication Lake(Aha Lake), while δ65Cu will be a new tracer for biologic activity in eutrophication Lake(Hongfeng Lake). Moreover, the vertical variation of temperature may be another significant factor affecting the copper isotope composition. 3. The variations of Zn isotopic composition of SPM in Hongfeng Lake and its main branches range from -0.29‰ to 0.26‰ and from -0.04‰ to 0.48‰, respectively while in Aha Lake and its main branches δ66Zn, they range from -0.18‰ to 0.27‰ and from -0.17‰ to 0.46‰, respectively, indicating that the SPM collected in their branches are enriched in heavy isotope. Zinc isotopic compositions in biological material show a larger variation and range from -0.35‰ to 0.57‰ illustrating that different materials from lacustrine ecosystem have unique isotopic signatures. The δ66Zn variation versus chlorophyll contents shows positive correlation (R=0.97) in Hongfeng Lake in summer, which can be most likely ascribed to the processes of adsorption or absorption of zinc onto algae. At the opposite, the zinc isotope composition in Aha Lake is mainly controlled by the water inputs from the catchment, hence the zinc isotope composition can be used as a good tracer of source materials. In addition, the zinc isotopes ratio of SPM in Hongfeng and Aha Lakes in summer are lower than in winter, sμggesting that the atmospheric deposition might have been another significant source of lighter zinc isotopes. Moreover, the variation of δ66Zn values in biological material is wider than in SPM, implying that inorganic processes controlling zinc isotope fractionation should be of second-order importance compared to biological factors. 4. The concentration of heavy metal such as Mn, Ni, Co, Cr, Cd and Pb in South Lake is higher than in North Lake, mainly caused by the inputs from the Yangchang River and seasonal variations in concentration of heavy metal are mainly affected by seasonal fluxes variation. Furthermore, dissolved Mn, Ni and Cr show seasonal variations, which can be ascribed to the seasonal changes of “oxygenic” and “anoxic” conditions at the water-sediment interface. At last, during the water-particle interaction process, DOC, FeO, MnO and algae reproduction induce variation of heavy metals speciation.
页数	137
语种	中文
文献类型	学位论文
条目标识符	http://ir.gyig.ac.cn/handle/352002/3388
专题	研究生_研究生_学位论文
推荐引用方式 GB/T 7714	梁莉莉. 贵州喀斯特高原湖泊物质循环过程中的铜锌同位素地球化学－以红枫湖、阿哈湖为例[D]. 地球化学研究所. 中国科学院地球化学研究所,2008.

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