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本文引用地质矿产部“七五”东北太平洋CCB53孔柱状沉积物(<63μm)的元素地球化学分析数据,采用“标准元素对比值法”定量分离Mn元素在不同物源(陆源、生物源、热液源和自生源)中的绝对含量,确定Mn元素地球化学本底,提取CCB53柱状沉积物中Mn元素的正、负异常。据此讨论了Mn元素发生活化、迁移和再沉淀的时间演化规律,即从沉积物的底部到顶部(22.42~0Ma),Mn元素经历了四个活化、迁移和沉淀旋回,分别为840~320、320~170、170~120和120~0。Mn元素的正、负异常分布与自生源组分和氧化还原环境的变化对比分析表明,Mn元素正、负异常分布与自生源组分的高→低变化规律和氧化还原条件的周期振荡紧密相关。早期成岩过程中发生的氧化还原环境的振荡是元素发生活化、迁移和沉淀的动因。 相似文献
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Gas hydrate research has significant importance for securing world energy resources, and has the potential to produce considerable
economic benefits. Previous studies have shown that the South China Sea is an area that harbors gas hydrates. However, there
is a lack of systematic investigations and understanding on the distribution of gas hydrate throughout the region. In this
paper, we applied mineral resource quantitative assessment techniques to forecast and estimate the potential distribution
of gas hydrate resources in the northern South China Sea. However, current hydrate samples from the South China Sea are too
few to produce models of occurrences. Thus, according to similarity and contrast principles of mineral outputs, we can use
a similar hydrate-mining environment with sufficient gas hydrate data as a testing ground for modeling northern South China
Sea gas hydrate conditions. We selected the Gulf of Mexico, which has extensively studied gas hydrates, to develop predictive
models of gas hydrate distributions, and to test errors in the model. Then, we compared the existing northern South China
Sea hydrate-mining data with the Gulf of Mexico characteristics, and collated the relevant data into the model. Subsequently,
we applied the model to the northern South China Sea to obtain the potential gas hydrate distribution of the area, and to
identify significant exploration targets. Finally, we evaluated the reliability of the predicted results. The south seabed
area of Taiwan Bank is recommended as a priority exploration target. The Zhujiang Mouth, Southeast Hainan, and Southwest Taiwan
Basins, including the South Bijia Basin, also are recommended as exploration target areas. In addition, the method in this
paper can provide a useful predictive approach for gas hydrate resource assessment, which gives a scientific basis for construction
and implementation of long-term planning for gas hydrate exploration and general exploitation of the seabed of China. 相似文献
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基于ArcGIS平台提取水深、坡度、粗糙度等地形特征,采用全覆盖多波来声纳测深数据,将南大西洋中脊研究区划分为4 267个统计单元,提取单元内地形特征的统计参数:均值、方差、最大值、最小值;经过统计筛选,最终选取水深均值、方差、最大值、最小值,坡度均值、方差、最大值、最小值共8个变量参与地形分类;利用K-均值方法进行非监督分类,将4 267个统计单元划分为5类地形,其中1 300个统计单元为裂谷,671个为裂谷壁,150个为内角高地斜坡,1 052个为高粗糙度的高地,1 093个为低粗糙度的次高地。将地形类型与地质调查结果进行初步关联,计算各类地形100网格见矿率系数,得到"内角高地斜坡"为热液硫化物发育的大概率地形类型,建议作为后继调查的重点勘探靶区。 相似文献
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