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陆相裂陷盆地深时源-汇系统关键地质问题及革新方向
刘强虎, 李志垚, 陈贺贺, 周子强, 谈明轩, 朱筱敏
PDF(9343 KB)
PDF(9343 KB)
陆相裂陷盆地深时源-汇系统关键地质问题及革新方向
Key Geological Issues and Innovation Directions in Deep -Time Source -to -Sink System of Continental Rift Basins
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依托洋陆边缘第四纪以来的解剖经验,源-汇系统研究已对陆相裂陷盆地开展深时探索实践,是当前国际沉积学研究的前沿领域,其中,涉及源-汇系统研究尺度与级次、物源区地貌演化与沉积碎屑产出、路径系统信号传递与示踪、多因素联合控制沉积-层序发育等关键问题亟待解决.针对上述问题,提出了火山作用改造沉积序列、古气候-植被群落调控风化效能、形态学与物源供给响应关联、路径系统交互模型预测、古水深-水动力制约砂体分散、正演模拟恢复源-汇过程及碳酸盐岩溶解质源-汇响应等潜在的革新方向,以期解决陆相裂陷盆地深时多驱动因素、多交互介质影响下沉积通量拾取及平衡恢复问题.此外,建议从多学科交叉融合及深时大数据系统多要素构建两方面拓展中国特色陆相深时源-汇系统研究内涵,服务能源矿产勘探预测.
The deep-time source-to-sink system in continental rift basins is a cutting-edge research topic in sedimentology and has been attempted by building on the research experience on the Quaternary ocean-land margins. Four key geological issues are raised, namely the research scale or level of the source-to-sink system, geomorphologic evolution and sediment output in the catchment, signal propagation and modification through the sediment routing system, and multifactorial joint control of sedimentary-stratigraphic development in the basin. In light of these issues, it proposes that the potential innovations might emerge from the research fields of volcanism-modified sedimentary sequences, palaeoclimate-vegetation community-regulated weathering efficacy, the relationship between catchment geomorphology and sediment supply, prediction of sediment routing system interaction models, paleo water depth-hydrodynamics constraints on sandstone dispersal, forward modeling to restore source-to-sink processes, and source-to-sink response of carbonate dissolved matter. By doing so, it hopes that the problems of sediment-flux pickup and balance restoration under the influence of multiple driving factors and interacting media in the continental deep-time rift basins can be effectively solved. In addition, it suggests that multi-disciplinary cross-integration and multi-element construction of deep-time big data system are two key directions for expanding the research connotation of continental deep-time source-to-sink system with Chinese characteristic and serving the exploration and prediction of energy minerals.
陆相深时源-汇系统 / 地貌形态 / 沉积信号 / 古气候-水体环境 / 大数据 / 关键问题 / 革新方向 / 沉积学
continental deep-time source-to-sink system / landform / sediment signal / paleoclimate-water environment / big data / key geological issue / innovation directions / sedimentology
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