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碳酸盐的溶解与保存是全球碳循环的重要组成部分,研究碳酸盐溶解作用对探索碳循环机制、理解全球气候变化机理等具有重要意义。本文通过西太平洋暖池核心区雅浦海沟南部附近海域108个表层沉积物和3个柱状沉积物样品中浮游有孔虫、底栖有孔虫和碳酸钙含量等变化特征分析了海底碳酸盐溶跃深度、补偿深度及其自中更新世以来的变化规律。表层沉积物碳酸盐含量、浮游与底栖有孔虫丰度、底栖有孔虫占有孔虫全群比例、底栖有孔虫群中胶结质壳比例等多种指标变化表明,本区现代碳酸盐溶跃面(carbonate lysocline depth, CLD)位于水深3800m附近,碳酸盐补偿深度(carbonate compensation depth, CCD)约为4800m。柱状样有孔虫溶解指数(foraminifera dissolution index, FDX)的变化表明,冰期碳酸盐溶解作用减弱,碳酸盐溶跃面和补偿深度变深;冰消期碳酸盐溶解作用增强,溶跃面和补偿深度变浅。位于现代溶跃面附近的柱状岩心碳酸盐含量呈现冰期高、间冰期低的“太平洋型”旋回特征,同时古生产力替代性指标的变化曲线与碳酸盐含量没有明显的相关性,说明中更新世以来的碳酸盐含量变化主要受溶解作用的控制,特别是在冰期- 间冰期转换时期更为明显。 相似文献
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对中国第四次北极科学考察期间在白令海北部获取的海水样品进行悬浮体含量及其颗粒组分特征的分析。结果表明,白令海陆架海区悬浮体含量大体呈现出表层浓度低而底层浓度高的特点。表层海水悬浮体含量在白令海峡西侧和陆架东侧靠近阿拉斯加沿岸含量较高,而底层海水中悬浮体含量则在白令海峡西侧,以及白令海陆架西南部的圣马修岛西北侧较高。陆架流系对底床物质的再悬浮作用致使白令海悬浮颗粒物浓度的高值区多位于近底层海水中。受白令陆坡流沿陆架坡折带输运作用,研究区西南部悬浮体浓度较高。白令海陆架水以及阿纳德尔流携带悬浮颗粒向北输运,使得底层悬浮体浓度呈现出自南向北逐渐减弱的模式。圣劳仑斯岛以北靠近楚科奇半岛一侧海域,受高营养盐的阿纳德尔流的影响,悬浮颗粒物以藻类为主;东侧阿拉斯加沿岸流区悬浮颗粒则以陆源的碎屑矿物为主。 相似文献
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广西钦州湾晚全新世红树林演变及对海平面变化的响应 总被引:2,自引:0,他引:2
Mangroves, widely distributed along the coasts of tropical China, are influenced by Asia monsoon, relative sea level change and enhanced human activity. To predict the impacts of future climate change on mangrove ecosystems, it can be understood by reconstructing past mangrove dynamics using proxies preserved in coastal sediments. In this study, we quantitatively partitioned buried organic matter(OM) sources, collected from a vulnerable mangrove swamp in the Qinzhou Bay of northwestern South China Sea, using a ternary end-member mixing model of δ~(13)C and C:N values. Mangrove-derived OM(MOM) contribution was used as a tracer for mangrove development since 2.34 cal ka BP. This information, together with paleoclimate records(i.e.,speleothem δ~(18)O values, sea level change, grain size parameters) and human activity, was used to divide mangrove development into three stages during the late Holocene: relative flourish(2.34–1.13 cal ka BP), relative degradation(1.13–0.15 cal ka BP) and further degradation(0.15–0 cal ka BP). Before 1.13 cal ka BP, mangroves flourished with a high MOM contribution((88.9±10.6)%), corresponding to stable and high sea level under a warm and humid climate. After 1.13 cal ka BP, rapid fall in relative sea level coupled with the strengthening of the Asian winter monsoon, resulted in mangrove degradation and MOM reduction((62.4±18.9)%). Compared with air temperature and precipitation, the relative sea level fall was the main controlling factor in mangrove development before entering the Anthropocene(the time of the Industrial Revolution). After ~150 cal a BP, reclamation of mangrove swamps to shrimp ponds is the main factor causing mangrove degradation and MOM reduction. 相似文献
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