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本文以济南市泉水补给区为研究对象,利用GIS空间分析方法,在其景观变化分析的基础上,参照中国陆地生态系统的生态服务价值系数,估算了泉水补给区生态服务功能价值变化,重点分析景观变化对研究区生态服务功能的影响,进而为区域可持续发展和城市建设提供理论支持。结果表明:(1)20世纪90年代以来,泉水补给区耕地和草地景观面积呈减少趋势,林地、园地和建设用地景观面积大幅增加,其中,以林地面积增加最大;从景观类型转化看,耕地与其他景观类型相互转化较为密切,特别是与建设用地和园地之间的转化;林地面积的增加主要来源于草地和耕地;(2)泉水补给区生态服务功能价值主要由林地和耕地景观生态服务价值构成,其变化对该研究区生态服务价值变化起决定作用;从生态服务价值构成类型来看,该地区土壤形成与保护服务功能单项价值所占比重最大,约占总服务功能价值的20%;(3)90年代以来,该地区总生态服务价值呈增加趋势;从单项服务价值变化来看,水源涵养、废物处理和食物生产服务功能价值则呈现出减小趋势,其中,以水源涵养减幅最大,为4.01%,主要是由该区建设用地增加,地面硬化面积增多而引起的。研究认为,济南市南部山区作为重要的泉水补给区,其生态服务功能尤为重要,特别是水源涵养功能,因此,研究区水源涵养服务功能价值的降低应在今后南部山区开发过程中得到足够的重视与保护,逐步增加泉水补给区的整体生态效益。 相似文献
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为解决勘探前期无井区或少井区圈闭的断层封闭性评价问题,基于地震、地质、测井等资料,采用物理模拟和地震资料相结合的方法,建立无井或少井区断层封闭性定量评价体系和评价数学模型,开发相应的评价软件.海拉尔盆地乌尔逊区块应用结果表明:借助高精度三维地震信息、物理模拟实验获取区域特征参数的评价方法,可以快速有效建立无井或少井区的断层封闭性评价数学模型,解决无井和少井区断层定量化三维空间表征与评价. 相似文献
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泥岩涂抹的连续性影响油气跨断层运移,在相似岩性、相似应力条件下,泥岩厚度和断距长度是影响泥岩涂抹连续性的主要因素。本文结合岩芯观察,借助三维定量物理模拟实验对泥岩涂抹的连续有效性进行了研究。结果表明:① 泥岩有效涂抹是决定断层封闭性的必要条件,涂抹连续厚度是封闭性评价的重要参数;② 受剪切作用在断层带中形成连续的泥岩涂抹油气封堵层,其涂抹形成过程分为3个阶段即泥岩层未错断阶段、泥岩剪切涂抹层形成阶段和涂抹层连续性破坏阶段,其中前2个阶段是泥岩有效涂抹阶段,在第3个阶段出现泥岩涂抹连续性破坏从而导致封堵油气失效;③ 基于非连续性等比例模型提出了新的断层封闭性评价参数——泥岩连续涂抹最小厚度,建立了泥岩失去涂抹连续性的非等比例评价理论和数学模型,形成了基于断裂带泥岩连续涂抹断层封闭性评价参数SGRnew新算法。结果表明,考虑了泥岩涂抹有效性而识别的断块圈闭可靠程度高,目标优选更准确,在研究区块圈闭评价应用效果好。 相似文献
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江河源区NDVI时空变化及其与气候因子的关系(英文) 总被引:5,自引:3,他引:2
The source regions of the Yangtze and Yellow rivers are important water conservation areas of China. In recent years, ecological deterioration trend of the source regions caused by global climate change and unreasonable resource development increased gradually. In this paper, the spatial distribution and dynamic change of vegetation cover in the source regions of the Yangtze and Yellow rivers are analyzed in recent 10 years based on 1-km resolution multitemporal SPOTVGT-DN data from 1998 to 2007. Meanwhile, the correlation relationships between air temperature, precipitation, shallow ground temperature and NDVI, which is 3×3 pixel at the center of Wudaoliang, Tuotuohe, Qumalai, Maduo, and Dari meteorological stations were analyzed. The results show that the NDVI values in these two source regions are increasing in recent 10 years. Spatial distribution of NDVI which was consistent with hydrothermal condition decreased from southeast to northwest of the source regions. NDVI with a value over 0.54 was mainly distributed in the southeastern source region of the Yellow River, and most NDVI values in the northwestern source region of the Yangtze River were less than 0.22. Spatial changing trend of NDVI has great difference and most parts in the source regions of the Yangtze and Yellow rivers witnessed indistinct change. The regions with marked increasing trend were mainly distributed on the south side of the Tongtian River, some part of Keqianqu, Tongtian, Chumaer, and Tuotuo rivers in the source region of the Yangtze River and Xingsuhai, and southern Dari county in the source region of the Yellow River. The regions with very marked increasing tendency were mainly distributed on the south side of Tongtian Rriver and sporadically distributed in hinterland of the source region of the Yangtze River. The north side of Tangula Range in the source region of the Yangtze River and Dari and Maduo counties in the source region of the Yellow River were areas in which NDVI changed with marked decreasing tendency. The NDVI change was980 Journal of Geographical Sciences positively correlated with average temperature, precipitation and shallow ground temperature. Shallow ground temperature had the greatest effect on NDVI change, and the second greatest factor influencing NDVI was average temperature. The correlation between NDVI and shallow ground temperature in the source regions of the Yangtze and Yellow rivers increased significantly with the depth of soil layer. 相似文献
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