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1.
TanGuang Gao Jie Liu TingJun Zhang ShiChang Kang ChuanKun Liu ShuFa Wang Mika Sillanpaa YuLan Zhang 《寒旱区科学》2020,(2):71-82
Understanding the interaction between groundwater and surface water in permafrost regions is essential to study flood frequencies and river water quality, especially in the high latitude/altitude basins. The application of heat tracing method,based on oscillating streambed temperature signals, is a promising geophysical method for identifying and quantifying the interaction between groundwater and surface water. Analytical analysis based on a one-dimensional convective-conductive heat transport equation combined with the fiber-optic distributed temperature sensing method was applied on a streambed of a mountainous permafrost region in the Yeniugou Basin, located in the upper Heihe River on the northern Tibetan Plateau. The results indicated that low connectivity existed between the stream and groundwater in permafrost regions.The interaction between surface water and groundwater increased with the thawing of the active layer. This study demonstrates that the heat tracing method can be applied to study surface water-groundwater interaction over temporal and spatial scales in permafrost regions. 相似文献
2.
Permafrost in China includes high latitude permafrost in northeastern China, alpine permafrost in northwestern China and high plateau permafrost on the Tibetan Plateau. The high altitude permafrost is about 92% of the total permafrost area in China. The south boundary or lower limit of the seasonally frozen ground is defined in accordance with the 0 oC isothermal line of mean air temperature in January, which is roughly corresponding to the line extending from the Qinling Mountains to the Huaihe River in the east and to the southeast boundary of the Tibetan Plateau in the west. Seasonal frozen ground occurs in large parts of the territory in northern China, including Northeast, North, Northwest China and the Tibetan Plateau except for permafrost regions, and accounting for about 55% of the land area of China. The southern limit of short-term frozen ground generally swings south and north along the 25o northern latitude line, occurring in the wet and warm subtropic monsoon climatic zone. Its area is less than 20% of the land area of China. 相似文献
3.
Studies on frozen ground of China 总被引:5,自引:0,他引:5
1ThestatusoffrozengroundinChinaBased on previous studies, Zhou and Guo (1982) summarized the distribution characteristics of permafrost in China and indicated that the permafrost area in China is about 215×104 km2, in which about 163.4×104 km2 is on the Tibetan Plateau. After mapping and zonation of frozen ground in 1983, Xu and Wang suggested that the areas of permafrost, seasonally frozen ground and temporal frozen ground in China were 206.8×104 km2, 513.7×104 km2 and 229.1×104 km2 … 相似文献
4.
中国冻土研究进展 总被引:6,自引:0,他引:6
Permafrost in China includes high latitude permafrost in northeastern China, alpine permafrost in northwestern China and high plateau permafrost on the Tibetan Plateau. The high altitude permafrost is about 92% of the total permafrost area in China. The south boundary or lower limit of the seasonally frozen ground is defined in accordance with the 0 ℃ isothermal line of mean air temperature in January, which is roughly corresponding to the line extending from the Qinling Mountains to the Huaihe River in the east and to the southeast boundary of the Tibetan Plateau in the west. Seasonal frozen ground occurs in large parts of the territory in northern China, including Northeast, North, Northwest China and the Tibetan Plateau except for permafrost regions, and accounting for about 55% of the land area of China. The southern limit of short-term frozen ground generally swings south and north along the 25° northern latitude line, occurring in the wet and warm subtropic monsoon climatic zone. Its area is less than 20% of the land area of China. 相似文献
5.
贵州高原北部发育平缓丘丛和深切峰丛2种喀斯特地貌组合,保存于喀斯特山间盆地的河流阶地对区域地貌演化具有指示意义。本文根据阶地发育特征和光释光(OSL)测年,分析阶地形成的时代和动力,结合区域地质背景,探讨构造抬升和河流侵蚀对黔北喀斯特地貌演化的驱动作用。结果显示,绥阳盆地T1阶地时代18.8~8.2 ka,T2时代144.4~104.1 ka;旺草盆地T1年龄为5.5 ka,T2年龄为45.1 ka。绥阳盆地阶地以漫滩相沉积物为主,旺草盆地阶地则多切割了白云岩基岩。分析认为,气候条件影响了阶地的沉积过程,但差异性构造抬升应为区域河流阶地差异发育的主要因素。阶地测年显示,旺草盆地的河流平均下切速率明显高于绥阳盆地,表明芙蓉江流域构造抬升和河流下切强度明显高于洋川河。在差异性构造抬升和河流侵蚀综合作用下,北部大娄山区形成了深切的喀斯特峰丛-峡谷地貌,南部乌江中游流域则发育以平坦盆地和宽缓丘丛为主的地貌组合。 相似文献
6.
极地天然气水合物分布于南北极大陆及其毗邻海域的沉积物(岩)中,与广泛分布的永久冻土带密切相关,资源潜力巨大。极地天然气水合物储层类型主要为富砂沉积物储层,能提供天然气水合物高浓度聚集所需的储集渗透性,最可能实现远景勘探和商业利用。随着全球气候变暖,北冰洋海冰加速融化和航道开通,北极地区蕴藏的丰富资源都将从潜在利益变成现实利益,各国的权益纷争也将愈演愈烈。本文综述了极地天然气水合物勘探开发现状和相关国家的水合物开发政策,依据中国海陆域天然气水合物勘查开发现状,提出了中国参与极地天然气水合物研究和开发的思路和途径,为中国极地资源开发利用战略提供参考。 相似文献
7.
青藏高原古地理环境研究 总被引:21,自引:2,他引:21
本文综述了最近 5 0年青藏高原古地理演化中一些基本问题研究进展。分析了中新世~上新世青藏古地理环境 ,高原在 3 6MaBP海拔不超过 10 0 0m ,此后强烈隆升。青藏高原最近三次冰期年代分别为 72 5~ 5 81、 2 89~ 136、 82~ 10kaBP ,冰期中不存在“大冰盖”。高原晚新生代重大古地理演化阶段和事件为 :38~ 2 2MaBP行星风系控制的热带 亚热带低地、 2 2~3 6MaBP古季风出现与主夷平面发育、 3 6~ 1 7MaBP高原强烈隆升与现代季风形成和现代河谷发育、 1 1~ 0 6MaBP高原抬升进入冰冻圈与大冰期出现、 0 15MaBP以来强烈隆升与高原内部干旱化。本文还讨论了高原古地理尚需深入研究的一些重大问题 相似文献
8.
青藏高原及其周边地区以独特的自然地理环境和复杂的地质构造,及其对全球环境和气候变化不可忽视的影响,长期以来一直受到国际科学家的关注。本文以SCIE和ESI数据库为数据源,检索2009-2015年间上述数据库报道的青藏高原及其周边地区研究文献及其引用情况,通过文献计量方法,采用多种分析工具,从多个角度对青藏高原及其周边地区研究现状与进展情况进行分析,在此基础上总结近年来国际青藏高原领域的研究态势,主要结论为:整体上近年来国际青藏高原领域研究规模和学术影响力呈现良好发展态势;研究实力上,中国、印度、美国仍稳居国家论文产出前三位,但青藏高原周边国家如巴基斯坦、尼泊尔发展较快,在机构层面上中国机构的整体优势逐渐扩大。中国的青藏高原研究呈现出量、质齐升的发展态势;青藏高原的发文期刊仍以地学、环境类期刊为主,高被引论文主要发表在高质量的综合类期刊上。青藏高原的研究学科持续完备,研究内容地域特色明显,研究主题包括青藏高原的隆升机制、高原各个圈层对全球气候变化的影响、高寒生态系统的生物多样性及对全球变暖的响应等。今后,中国青藏高原研究应着力聚焦前沿科学问题,促进多学科交叉融合,提升协同化集成化自主科研创新能力,产出具有国际影响力的重大科学成果,为“一带一路”战略实施和区域生态环境管理提供科技支撑。 相似文献
9.
2.5 Ma以来柴达木盆地的气候干湿变化特征及其原因 总被引:7,自引:5,他引:7
长期以来,一直认为柴达木盆地第四纪气候在波动中向干旱方向发展。原因是青藏高原的隆升阻挡了来自印度洋、孟加拉湾的水汽。然而,来自柴达木盆地新的证据表明,柴达木盆地第四纪气候演变的总体趋势是冰期越来越干燥,间冰期干燥程度却存在减弱的趋势。并且这种变化是呈阶段性的。最明显的阶段划分应在0.8-0.6Ma前后。这种现象可以用青藏高原的隆升做出比较合理的解释:青藏高原的隆升,不仅通过增强冬季亚洲高压(西伯利亚高压)使冬季风增强,使东亚季风区冰期气候更加干燥寒冷,而且还可以通过增强夏季亚洲低压(印度低压),使夏季风增强、间冰期气候更加温暖湿润,从而使得中国季风区冰期-间冰期的气候变差增大。可是,柴达木盆地位于青藏高原北缘,我国西北内陆区受夏季风影响较弱,间冰期或者湿润期湿润程度的增大如何与高原隆升和季风系统的调整相联系,还有待于进一步的研究。 相似文献
10.
Jin-Gen Dai Matthew Fox David L. Shuster Jeremy Hourigan Xu Han Ya-Lin Li Cheng-Shan Wang 《Basin Research》2020,32(5):894-915
The uplift and associated exhumation of the Tibetan Plateau has been widely considered a key control of Cenozoic global cooling. The south-central parts of this plateau experienced rapid exhumation during the Cretaceous–Palaeocene periods. When and how the northern part was exhumed, however, remains controversial. The Hoh Xil Basin (HXB) is the largest late Cretaceous–Cenozoic sedimentary basin in the northern part, and it preserves the archives of the exhumation history. We present detrital apatite and zircon (U-Th)/He data from late Cretaceous–Cenozoic sedimentary rocks of the western and eastern HXB. These data, combined with regional geological constraints and interpreted with inverse and forward model of sediment deposition and burial reheating, suggest that the occurrence of ca. 4–2.7 km and ca. 4–2.3 km of vertical exhumation initiated at ca. 30–25 Ma and 40–35 Ma in the eastern and western HXB respectively. The initial differential exhumation of the eastern HXB and the western HXB might be controlled by the oblique subduction of the Qaidam block beneath the HXB. The initial exhumation timing in the northern Tibetan Plateau is younger than that in the south-central parts. This reveals an episodic exhumation of the Tibetan Plateau compared to models of synchronous Miocene exhumation of the entire plateau and the early Eocene exhumation of the northern Tibetan Plateau shortly after the India–Asia collision. One possible mechanism to account for outward growth is crustal shortening. A simple model of uplift and exhumation would predict a maximum of 0.8 km of surface uplift after upper crustal shortening during 30–27 Ma, which is insufficient to explain the high elevations currently observed. One way to increase elevation without changing exhumation rates and to decouple uplift from upper crustal shortening is through the combined effects of continental subduction, mantle lithosphere removal and magmatic inflation. 相似文献
11.
受全球气候变化和人类活动影响,青藏高原上的土地沙漠化正呈现加速发展态势。沙漠化产生的风沙堆积势必改变地表辐射和能量平衡状况,对较为敏感和脆弱的多年冻土环境造成影响,并可能影响青藏铁路路基的稳定性。因此,研究积沙对多年冻土的影响对于高原沙害防治、多年冻土保护和道路工程建设都具有重要的理论及现实意义。目前,前人已在青藏高原地表能量平衡研究方面取得了一些成果,并开始关注积沙对冻土温度影响问题。然而,由于已有观测资料的连续性、同步性和可比性等局限,对积沙地表辐射和能量平衡方面的研究还比较薄弱,积沙对冻土温度过程影响的研究结果尚不一致,而积沙对路基影响的问题也亟待开展研究。为此,本文提出了加强定位观测、开展室内低温实验以及数值模拟等建议,以期对今后的深入研究起到抛砖引玉作用。 相似文献
12.
Constraining basin thermal history and petroleum generation using palaeoclimate data in the Piceance Basin,Colorado 
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下载免费PDF全文 Yao Tong Daniel E. Ibarra Jeremy K. Caves Tapan Mukerji Stephan A. Graham 《Basin Research》2017,29(4):542-553
Careful assessment of basin thermal history is critical to modelling petroleum generation in sedimentary basins. In this paper, we propose a novel approach to constraining basin thermal history using palaeoclimate temperature reconstructions and study its impact on estimating source rock maturation and hydrocarbon generation in a terrestrial sedimentary basin. We compile mean annual temperature (MAT) estimates from macroflora assemblage data to capture past surface temperature variation for the Piceance Basin, a high‐elevation, intermontane, sedimentary basin in Colorado, USA. We use macroflora assemblage data to constrain the temporal evolution of the upper thermal boundary condition and to capture the temperature change with basin uplift. We compare these results with the case where the upper thermal boundary condition is based solely upon a simplified latitudinal temperature estimate with no elevation effect. For illustrative purposes, 2 one‐dimensional (1‐D) basin models are constructed using these two different upper thermal boundary condition scenarios and additional geological and geochemical input data in order to investigate the impact of the upper thermal boundary condition on petroleum source rock maturation and kerogen transformation processes. The basin model predictions indicate that the source rock maturation is very sensitive to the upper thermal boundary condition for terrestrial basins with variable elevation histories. The models show substantial differences in source rock maturation histories and kerogen transformation ratio over geologic time. Vitrinite reflectance decreases by 0.21%Ro, source rock transformation ratio decreases 10.5% and hydrocarbon mass generation decreases by 16% using the macroflora assemblage data. In addition, we find that by using the macroflora assemblage data, the modelled depth profiles of vitrinite reflectance better matches present‐day measurements. These differences demonstrate the importance of constraining thermal boundary conditions, which can be addressed by palaeotemperature reconstructions from palaeoclimate and palaeo‐elevation data for many terrestrial basins. Although the palaeotemperature reconstruction compiled for this study is region specific, the approach presented here is generally applicable for other terrestrial basin settings, particularly basins which have undergone substantial subaerial elevation change over time. 相似文献
13.
Quaternary geomorphological evolution of the Kunlun Pass area and uplift of the Qinghai-Xizang (Tibet) Plateau 总被引:6,自引:0,他引:6
Yongqiu Wu Zhijiu Cui Gengnian Liu Daokai Ge Jiarun Yin Qinghai Xu Qiqing Pang 《Geomorphology》2001,36(3-4)
There is a set of Late Cenozoic sediments in the Kunlun Pass area, Tibetan Plateau, China. Paleomagnetic, ESR and TL dating suggest that they date from the Late Pliocene to the Early Pleistocene. Analyses of stratigraphy, sedimentary characteristic, and evolution of the fauna and flora indicate that, from the Pliocene to the early Quaternary (about 5–1.1 Ma BP), there was a relatively warm and humid environment, and a paleolake occurred around the Kunlun Pass. The elevation of the Kunlun Pass area was no more than 1500 m, and only one low topographic divide existed between the Qaidam Basin and the Kunlun Pass Basin. The geomorphic pattern in the Kunlun Pass area was influenced by the Kunlun–Yellow River Tectonic Movement 1.1–0.6 Ma BP. The Wangkun Glaciation (0.7–0.5 Ma) is the maximum Quaternary glaciation in the Pass and in other areas of the Plateau. During the glaciation, the area of the glaciers was 3–5 times larger than that of the present glacier in the Pass area. There was no Xidatan Valley that time. The extreme geomorphic changes in the Kunlun Pass area reflect an abrupt uplift of the Tibet Plateau during the Early and Middle Pleistocene. This uplift of the Plateau has significance on both the Plateau itself and the surrounding area. 相似文献
14.
南京下蜀黄土红外释光地层年代学 总被引:7,自引:1,他引:6
下蜀黄土地层年代学对于理解季风环流时空格局演化及其与青藏高原阶段性隆升的关系十分重要。作者基于下蜀黄土红外释光测年和下蜀黄土及黄土高原洛川;剖面磁化率序列的对比分析,认为下蜀黄土第一层黄土层形成于末次冰期,最底部的黄土层与洛川的 L5相当。因而下蜀黄土应相当于黄土高原LS以来的风成堆积,其底界年代约为 500 ka。也就是说,在 500 ka左右黄土堆积的南界已达长江下游地区。这可能是因为其时青藏高原的隆升已到达一特殊高度,对东亚季风演化的影响成为一个转折点,加强了东亚季风的强度。 相似文献
15.
藏北高原土壤温度分布的纬向效应和高度效应 总被引:6,自引:2,他引:4
利用GAME-Tibet野外观测期间所得藏北高原不同地点土壤温度资料,对藏北高原土壤温度分布纬向地带性和垂直地带性特征进行分析,结果表明夏季土壤温度分布主要表现为高度效应,而冬季土壤温度分布主要表现为纬度效应,年平均土壤温度分布是纬度效应和高度效应综合作用的结果。 相似文献
16.
The Cenozoic continental sedimentary basins in eastern China are rich in lacustrine source rocks. Based on their paleogeographic location and fossils, these basins can be grouped into inland and near-shore basins. Before the collision of India and Eurasia about 45 million years ago, the inland basins were dominated by arid climates that were unfavorable for the substantial preservation of oil source rocks. In contrast, the contemporary near-shore basins experienced alternating arid and humid climates, probably induced by sea level changes, which produced conditions that favoured the formation and preservation of oil source rocks. With the rise of the Tibetan Plateau, the Asian monsoon was initiated or significantly intensified in the Late Eocene. This, in turn, changed the arid climates in the inland basins to humid or to alternating arid and humid, providing ideal conditions for the formation and preservation of lacustrine source rocks in the inland basins. The evidence suggests that Tibetan uplift played a crucial role in the generation and preservation of the Cenozoic lacustrine source rocks in eastern China.This is the third paper in a series of papers published in this issue on Climatic and Tectonic Rhythms in Lake Deposits. 相似文献
17.
18.
青海省祁连山南缘多年冻土区发现天然气水合物,这是在我国冻土区的首次发现。虽然青海天然气水合物的发现与开发具有诸如能源战略等重要意义,但在多年冻土区开发天然气水合物具有巨大的环境影响风险,包括CH4释放对全球气候的影响、冻土层的退化和高寒草甸的破坏、开采过程中可能出现的塌方和地陷等。可以通过采用安全可靠的具有针对性的开发技术和工艺,将青海天然气水合物开发纳入柴达木循环经济范畴,采用CO2捕获和封存技术,以及控制工程过程等来防治天然气水合物开发过程中的环境影响。 相似文献
19.
考虑局地因素坡向影响的青藏高原工程走廊冻土分布与制图研究 总被引:2,自引:0,他引:2
通过Pearson相关性分析,选取对青藏高原工程走廊多年冻土分布影响较大、在GIS技术支持下较容易量化的坡向因子,结合走廊内2000—2010年29个钻孔点的地温监测数据,建立了年均地温与坡向、纬度和高程的关系模型。根据高原冻土工程地温分带指标,制作了工程走廊内符合实际的冻土分布图,由面积统计结果知:多年冻土区占整个区域的94.06%,其中,低温稳定带占多年冻土区面积的15.94%,主要分布在风火山和可可西里的高山基岩区;低温基本稳定带占16.97%,主要分布在风火山及可可西里丘陵地带;高温不稳定带占48%,主要分布于可可西里和北麓河盆地东缘;高温极不稳地带占19.09%,主要分布于北麓河盆地和楚玛尔河高平原。 相似文献
20.
In the offshore part of Beaufort–Mackenzie Basin depth of methane hydrate stability reaches more than 1.5 km. However, there are areas in the western part of the basin where there are no conditions of methane hydrate stability. Construction of the first contour maps displaying thickness of hydrate stability zones as well as hydrate stability zone thicknesses below permafrost in the offshore area, shows that these zones can reach 1200 m and 900 m, respectively. Depth to the base of ice-bearing relict permafrost under the sea (depth of the –1°C isotherm-ice-bearing permafrost base) and regional variations of geothermal gradient are the main controlling factors. Hydrostatic pressures in the upper 1500 m are the rule. History of methane hydrate stability zone is related mainly to the history of permafrost and it reached maximum depth in early Holocene. More recently, the permafrost and hydrate zone is diminishing because of sea transgression. Reevaluation of the location of possible gas hydrate occurrences is done from the analysis of well logs and other indicators in conjunction with knowledge of the hydrate stability zone. In the offshore Beaufort–Mackenzie Basin, methane hydrate occurs in 21 wells. Nine of these locations coincides with underlying conventional hydrocarbon occurrences. Previous analyses place some of the hydrate occurrences at greater depths than proposed for the methane hydrate-stability zone described in this study. Interpretation of geological cross sections and maps of geological sequences reveals that hydrates are occurring in the Iperk–Kugmallit sequence. Hydrate–gas contact zones, however, are possible in numerous situations. As there are no significant geological seals in the deeper part of the offshore basin (all hydrates are within Iperk), it is suggested that overlying permafrost and hydrate stability zone acted as the only trap for upward migrating gas during the last tens of thousand of years (i.e., Sangamonian to Holocene). 相似文献