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1.
笔者回顾了近年来中国化探的一些理论与方法技术上的重大新进展,立足于地球化学填图基础上的矿集区、多元素异常集结区与地球化学块体理论,利用地球化学资料进行矿产资源潜力评价与稀有分散元素独立成矿的可能性评价,利用地球化学资料进行成矿岩体演化与中国西南大地幔柱的初步研究,这些探索性的研究均取得了令人鼓舞的成就。化探方法技术的应用成果显著,如地球化学填图与矿产勘查一体化,多元素分析与分析质量监控方法不断完善外来物覆盖浅钻取样,深穿透地球化学方法,全国生态、农业、环境地球化学调查,全球地球化学填图方法研究等。在回顾近年化探成果的基础上,提出中国化探在21世纪的发展,整体思路是立足于地球化学填图及地球化学填图与矿产勘查一体化。需要有将研究、填图、调查、勘查、工程一体化的大科学计划。提出了涉及地球化学填图、矿产勘查与综合利用、能源勘查、生态环境调查、全球变化研究等的12个重点发展方向。 相似文献
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新一轮全球地球化学填图:中国的机遇和挑战 总被引:4,自引:0,他引:4
论述从1988年联合国教科文组织相继批准实施国际地球化学填图(IGCP259)和全球地球化学基准(IGCP360)项目以来,中国和欧洲在制定全球地球化学填图的方法指南及技术标准方面作出的决定性贡献。文中指出,中国的"环境地球化学监控网络及动态地球化学填图"项目、欧洲的FOREGS地球化学基准值填图项目为全球其他国家开展类似工作提供了示范,但地球化学家预期10年内获得全球地表地球化学概貌的愿望至今未能实现。挪威和中国的地球化学家通过IAHS/ICCE正在酝酿"Global geochemical mapping and the sediment-bound flux of major world rivers"重大国际合作项目,以开展新一轮全球地球化学填图。通过国际极地年,IPY317项目首先从北极地区启动。新一轮全球地球化学填图项目计划以中国提出的"全球地球化学填图的泛滥平原沉积物采样草案"和挪威提出的"三角洲中河漫滩沉积物的采样草案"作为实施方案,因而巩固和扩大了中国地球化学填图技术在全球的优势地位。论文在分析中国面临的机遇与挑战后,建议政府主管部门对新一轮全球地球化学填图给予优先支持。 相似文献
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Geochemical mapping in China 总被引:5,自引:0,他引:5
China's National Geochemical Mapping Project (Regional Geochemistry-National Reconnaissance, RGNR project) was initiated in 1979. From 1978 to 1982, cooperative research projects were carried out for the preparation and distribution of standard reference samples and for the development of field sampling techniques, multi-element analytical methodology and a unified data quality monitoring procedure. Large pilot surveys were also commenced in several provinces. After five years of technical preparation, the project came into its full implementation. More than 5 million km2 of Chinese land surface has been covered by this project. During 1993–1995, another national geochemical project, under the name of ‘Environmental geochemical monitoring network and dynamic geochemical maps in China’ as a pilot survey to choose the suitable sampling medium for the global geochemical mapping application, was carried out in China. The remarkable achievements of China's geochemical mapping projects are widely recognized. Nearly 66% of new discoveries of economic mineralization by MGMR were attributed to the RGNR project. New concepts and new methodologies have emerged through these projects. They also made a great contribution to the international activity toward standardization of geochemical mapping methodology and the possible realization of wide-spaced global geochemical mapping. 相似文献
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More than 40 national and regional geochemical mapping projects in the world carried out from 1973 to 1988 do not conform to common standards. In particular they have many analytical deficiencies. In the period 1988 to 1992, the International Geochemical Mapping project (Project 259 of UNESCO's IGCP Program) prepared recommendations designed to standardize geochemical mapping methods. The analytical requirements are an essential component of the overall recommendations. They included the following: 71 elements should be analyzed in future mapping projects; the detection limits of trace and ultratrace elements must be lower than the corresponding crustal abundances; and the Chinese GSD and Canadian STSD standard sample series should be used for the correlation of global data. A proposal was also made to collect 5000 composite samples, at very low sampling densities to cover the whole Earth's land surface. In 1997 an IUGS Working Group on Global Geochemical Baselines was formed to continue the work which began with IGCP 259. From 1997 up to now, new progress has been made especially in China and FOREGS countries under the aegis of this working group, including the study of suitable sampling media, development of a multi-element analytical system, new proficiency test for selection of competent laboratories and role of wide-spaced mapping in mineral exploration. One of the major problems awaiting solution has been the inability of many laboratories to meet the IGCP recommendations to generate high quality geochemical maps. Fortunately several laboratories in China and Europe have demonstrated an ability to meet the requirements and they will be well placed to render technical assistance to other countries. 相似文献
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星罗棋布的热带珊瑚作为海洋环境的信息载体,具有分辨率高、时间跨度大、记录连续完整、体系封闭性好、蕴涵的信息丰富、可选择的代用指标多、测定简便和易于定年等特点。珊瑚有效地记录了全球环境变化的诸多信息,已成为研究过去(如末次间冰期以来)和近代(如数十至数百年以来)的气候—环境变率和可预测性(PAGES CLIVAR)领域重要的环境载体。以全球变化为背景,对近年来珊瑚环境代用指标的研究成果进行评述。重点讨论了珊瑚氧同位素和微量元素比值等指标在海表温度(SST)变化、海气交换程度、季风强弱、厄尔尼诺—南方涛动(ENSO)发生的频率和强度,以及它们之间的相互作用等全球变化的核心问题上的研究进展,并展望了南海珊瑚在高分辨率全球变化研究中的地位与方向。 相似文献
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国际地球化学填图新进展 总被引:3,自引:1,他引:3
欧洲和中国在国际地球化学填图中起着积极而重要的作用,而且进展也是最显著的。欧洲地球化学基准值填图计划于1996年被欧洲26个国家地质调查局长论坛(FOREGS)正式批准。经过近10年的工作,于2005年出版了电子版欧洲地球化学图集。中国不仅自己开展了多层次地球化学填图计划,而且还与发展中国家合作开展了全球尺度和成矿带尺度地球化学填图合作。欧洲和中国无论是在全球尺度,还是在区域尺度地球化学填图做法上都存在较大的差异。在采样介质上中国使用统一的采样介质,在分析技术上中国使用几种大型设备作为骨干配合使用多方法分析系统;欧洲恰恰相反,欧洲在采样介质上趋向于多介质,而分析技术上只使用少数几种大型设备。欧洲的做法尽管使用多介质采样获得了元素在更多天然介质中的分布信息,但使用单一分析技术,使得很多关键元素没有分析出来,如贵金属元素Ag,Au,Ir,Os,Pd,Pt,Rh,Ru;卤族元素F,Cl,Br,I;分散元素Ge,In,Se,Te;与生命密切相关的元素N,S,B等。尽管欧洲强调以环境为目的,但很多与环境密切相关的元素都没有分析,所以欧洲的全球尺度地球化学填图的信息量大打折扣。这些不统一的做法,特别是在全球尺度地球化学填图不统一的做法,会影响到以后全球地球化学图的编制。 相似文献
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勘查地球化学的现状与未来展望 总被引:28,自引:2,他引:28
勘查地球化学在过去50年发展迅速,并取得巨大成功。从它近年的发展及在中国北京与澳大利亚Townsville召开的第16届及第17届国际地球化学勘查学术讨论会上所表现的创新与非传统性看来,勘查地球化学正在从经验式阶段向革新技术与加强理论研究的新阶段过渡。其主要标志是由于国际地球化学填图研究的进展及各种宽阔地球化学模式的认识,地球化学勘查将逐步成为能左右矿产勘查部署的战略性方法,各种新技术的出现使隐伏区找矿特别是找巨型矿床正在取得重大突破。高质量的地球化学图还将使今后的环境研究更具全球眼光,中国的工作是这些方 相似文献
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作指出了1973年至今世界上50余项地球化学填图计划中普遍存在的缺陷大都涉及分析问题。1988-1992年实施的国际地质对比计划IGCP259项目旨在使全世界地球化学填图方法标准化。在此项目中对分析问题提出了若干规定,主要是要求今后的填图计划应统一分析71种元素,痕量及超痕量元素的检出限必须低于相应的地壳丰度值及采用中国的GSD和加拿大的STSD标样系列,以使全球数据可以对比,在其后开始延续至今的全球地球化学填图计划IGCP360,旨在用极低密度采样早日覆盖全球大陆,讨论了正在实行的两种极低密度采样方案,并提出通过极低密度采集地极少量样品示范性实现IGCP259项目对分析要求的具体建议。 相似文献
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中国金的地球化学省及其成因的微观解释 总被引:3,自引:0,他引:3
利用全国1:20万区域化探扫面600×104km2和东天山、中蒙边界1:100万地球化学填图86×104km2的金分析数据,在全国圈定了15处金的地球化学省集中区,并发现与金矿成矿带或大型矿集区有关的地球化学省都具有多层套合结构特征。这种具有多层套合特征的地球化学省的形成是由高背景岩石、成矿作用和矿床风化产生的次生分散相互叠加的结果。高背景岩石提供了成矿元素的初始物源,成矿过程使得元素的进一步活化和富集,矿床风化产生元素的点源分散进一步形成叠加异常浓集中心,最后形成了具有多层套合的地球化学异常。通过使用微米和纳米观测手段发现地球化学样品中存在大量微米至纳米级金微粒,这种金微粒具有极强的活动性,能被各种营力作长距离搬运,形成了大规模具有多层套合特征的金地球化学省。 相似文献
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Outlines of New Global Geochemical Mapping Program 总被引:3,自引:1,他引:2
<正>Since 1988,great efforts and enthusiasm had been paid by applied geochemists in the implementation of global geochemical mapping through the International Geological Correlation Program's Projects 259 and 360,and the Task Group on‘Global Geochemical Baselines' established by the International Union of Geological Sciences(IUGS),in collaboration with the International Association of Geochemistry(IAGC).But how to use extremely low-density sampling to obtain a global picture of the distribution of most elements in the periodic table in a reasonably short time is still a great challenge faced by the applied geochemistry community.It will depend on the continuous development of new mapping concept,and the advisable and courageous innovation of methodology for searching other suitable sample media and sampling layout.Based on the encouragement results obtained from the representativeness study of delta sediments conducted at the mouth of Yangtze River,and at the mouths of its four major tributary,it is expected to broadly apply the geochemical fractal self-similarity nature to main rivers and their estuaries with catchments up to hundreds of thousands or over a million square kilometers in the world.With this new mapping concept,a new outlines of a Global Geochemical Mapping Program was advanced and the establishment of an International Research Center of Global Geochemical Mapping was also suggested to facilitate the programs implementations. 相似文献
12.
The Sample Catchment Basin (SCB) mapping technique extends the representativeness of the geochemical features of stream sediments to the surface of the whole upstream drainage basin. SCB boundaries clash with the water divides traced from each sampling point and are limited upstream by the presence of further SCBs. They are also assumed to represent the elementary map unit. The rank of SCBs can be defined counting the number of upstream SCBs along the branches of a fluvial network. The presence of low rank SCBs minimizes the statistical redundancy of measures. The SCB technique is particularly suitable for the geochemical mapping of mountainous or hilly areas and to correctly display the information into a morphological context. This approach can be also valuable in the case of low sampling density, inhomogeneous sampling schemes, and especially when very accurate evaluations of the spatial distribution of chemicals (with natural or anthropogenic origin) are required. 相似文献
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地球化学省与地球化学边界 总被引:17,自引:1,他引:17
根据中国大陆各种类型壳,幔源岩石和矿石的大量铅-锶-钕同位素资料,及全球特别是东亚大陆块体广泛的同位素与元素体系对比,发展了地球化学块体划分的同位素地球化学指标和填图方法,在此基础上开展了中国大陆的大尺度铅同位素矢量填图,确定了中国大陆主要地球化学省和地球化学急变带(边界),地球化学边界的形成与板块的斜结合以及结合以后岩石圈结构调整产生的克拉通边界密切相关,地球化学边界与重力正异常梯度带,莫霍面梯度带以及正负磁异常转换带存在平行和交错两种关系,研究表明地球化学急变带控制了中国大陆90%以上的超大型金,铜,锡,银,镍,铅-锌,铀,钾盐,硼镁,磷等(33个)和10个以上的大型矿集区。地球化学省划分制约着全球油气资源分布,而地球化学边界则具体控制着克拉通边缘前陆盆地中产油气位置,陆内六级以上强破坏性的浅源地震与克拉通边界-地球化学边界关系十分密切,喀斯特溶洞奇观的出现与地球化学边界关系同样相当密切,根据铅同位素地球化学填图确定的区域背景值可以对铅污染作出快速的定量评价。 相似文献
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固体矿产地球化学勘查进展与成果 总被引:4,自引:0,他引:4
为庆祝第三十届国际地质大会在北京召开,让世界各国地质同行们了解中国地矿部门固体矿产地球化学勘查工作的进展,本文主要介绍我国地球化学勘查的成果。近十五年来已完成区域化探覆盖面积517万km2,中比例尺化探普查面积约90万km2,发现各类化探异常约4.3万处,通过检查化探异常和工程验证发现具工业价值的大、中、小型矿床569处,找矿效果非常显着,特别是化探找金、银矿方面取得突破性成果,化探方法技术不断提高和广泛推广。特殊景观区的野外工作方法、化探样品微量、痕量元素测试方法技术、化探异常的查证方法及化探数据处理与成图等方面均接近或达到国际水平。回顾过去,地球化学勘查进展迅速,成果丰硕,技术水平不断提高。展望未来,地球化学勘查目标明确,任务繁重,地质找矿潜力巨大。 相似文献
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地球化学填图与地球化学勘查 总被引:3,自引:0,他引:3
在中国与西方国家,地球化学填图的目的与做法并不相同,西方的地球化学填图是由研究机构开展的,使用等离子焰光量计、X射线荧光光谱仪等大型仪器进行多元素分析,目的是取得多种元素在地球表层分布的基础性资料。地球化学勘查则由矿业公司主要分析少量成矿元素,目的是为了找矿。而中国的地球化学填图计划却做出了巨大努力,使地球化学填图取得的资料既有学术价值又对矿产勘查具有重大的实用意义。本文详细讨论了西方国家与中国地球化学填图与地球化学勘查的思路、方法与技术的演变,并瞻望了地球化学填图在21世纪的巨大发展前景。 相似文献
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本文介绍谢学锦先生快速进行区域地球化学填图的计划在西藏取得的成果。区域水化学填图可分析66个指标,效率高,成本低,见效快;同时水化学填图的空间定位和分辨率比采集土壤样品的填图会差一些。西藏地球化学填图成果呈现了一定的规律性,例如西藏66种元素的地球化学图中,有三分之二沿雅鲁藏布江缝合带出现异常带。西藏许多元素的分布受雅鲁藏布江缝合带影响,是因为特提斯洋原有的一些元素残留在雅鲁藏布江缝合带两侧。氧化钾、氧化钠沿雅鲁藏布江缝合地带出现含量高的异常带,可见特提斯洋中丰富的钾、钠成分残留在代表大洋封闭的雅鲁藏布江缝合带两侧。沿雅鲁藏布江缝合地带氧化钙出现含量低的异常带,可用特提斯洋中的碳汇作用来解释,即特提斯洋中的钙由于碳汇作用变成碳酸盐岩石,氧化钙出现含量低的异常。西藏的地球化学图对矿产勘查和生态环境研究也具有一定意义。 相似文献
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《Applied Geochemistry》2001,16(11-12):1291-1308
Land degradation and pollution caused by population pressure and economic development pose a threat to the sustainability of the earth's surface, especially in tropical regions where a long history of chemical weathering has made the surface environment particularly fragile. Systematic baseline geochemical data provide a means of monitoring the state of the environment and identifying problem areas. Regional surveys have already been carried out in some countries, and with increased national and international funding they can be extended to cover the rest of the land surface of the globe. Preparations have been made, under the auspices of the International Union of Geological Surveys (IUGS) and the International Association of Geochemistry and Cosmochemistry (IAGC) for the establishment of just such an integrated global database. 相似文献
19.
Xu Zijuan Zuo Xinxin Fan Bailing Ding Xinquan Zhang Xiaodong Li Zichuan Yan Cuixiang Song Zhaoliang 《地球科学进展》2017,32(2):151-159
Phytoliths, also called amorphous silica particles, have a great geochemical stability and could occlude a certain amount of organic carbon during the forming process. At present, phytolith-occluded carbon (PhytOC) is recognized as one of long-term stable carbon sequestration mechanisms and has significant influence on regulating global climate change. At the same time, PhytOC isotope research has great value for paleo-environment, paleo-climate reconstruction and other fields. Therefore, more scholars pay attention to the PhytOC geochemical research. Based on the current research status, we summarized the current state of understading about phytolith forming process, elemental composition, geochemical stability, PhytOC sink and PhytOC isotope application for paleo-environment reconstruction. We also summarized the main problems of geochemical research on phytolith and PhytOC, which will make great contribution to further research on phytolith geochemical research. 相似文献
20.
Urban geochemistry is a unique discipline that is distinguished from general geochemistry by the complex infrastructure and intense human activities associated with concentrated population centers. As stated by Thornton (1991) “This subject is concerned with the complex interactions and relationships between chemical elements and their compounds in the urban environment, the influence of past and present human and industrial activities on these, and the impacts or effects of geochemical parameters in urban areas on plant, animal and human health.” Urban areas present special challenges to geochemists attempting to understand geochemical states and fluxes. On the 5–6 of August, 2014, the first meeting of the reorganized Urban Geochemistry Working Group of the International Association of GeoChemistry (IAGC) was held in Columbus, Ohio, United States. Two goals of the meeting were to develop the overall scope, and a general definition of urban geochemistry. Five grand themes were developed: 1) recognizing the urban geochemical signature; 2) recognizing the legacy of altered hydrologic and geochemical cycles in urban environments; 3) measuring the urban geochemical signature; 4) understanding the urban influence on geochemical cycles from the continuous development and erosion of physical infrastructure and episodic perturbations; and 5) relating urban geochemistry to human and environmental health and policy. After synthesizing the discussion of these themes we offer the following perspective on the science of urban geochemistry building on the work of Thornton (1991): Urban geochemistry as a scientific discipline provides valuable information on the chemical composition of environments that support large populations and are critical to human health and well-being. Research into urban geochemistry seeks to 1) elucidate and quantify the sources, transport, transformations, and fate of chemicals in the urban environment, 2) recognize the spatial and temporal (including legacies) variability in these processes, and 3) integrate urban studies into global perspectives on climate change, biogeochemical cycles, and human and ecosystem health. We hope that this discussion will encourage other geochemists to engage in challenges unique to urban systems, as well as provide a framework for the future of urban geochemistry research. 相似文献