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41.
《China Geology》2018,1(3):331-345
The Gonghe Basin, a Cenozoic down-warped basin, is located in the northeastern part of the Qinghai-Xizang (Tibetan) Plateau, and spread over important nodes of the transfer of multiple blocks in the central orogenic belt in the NWW direction. It is also called “Qin Kun Fork” and “Gonghe Gap”. The basin has a high heat flow value and obvious thermal anomaly. The geothermal resources are mainly hot dry rock and underground hot water. In recent years, the mechanism of geothermal formation within the basin has been controversial. On the basis of understanding the knowledge of predecessors, this paper proposes the geothermal formation mechanism of the “heat source–heat transfer–heat reservoir and caprock–thermal system” of the Gonghe Basin from the perspective of a geological background through data integration-integrated research-expert, discussion-graph, compilation-field verification and other processes: (1) Heat source: geophysical exploration and radioisotope calculations show that the heat source of heat in the basin has both the contribution of mantle and the participation of the earth’s crust, but mainly the contribution of the deep mantle. (2) Heat transfer: The petrological properties of the basin and the exposed structure position of the surface hot springs show that one transfer mode is the material of the mantle source upwells and invades from the bottom, directly injecting heat; the other is that the deep fault conducts the deep heat of the basin to the middle and lower parts of the earth’s crust, then the secondary fracture transfers the heat to the shallow part. (3) Heat reservoir and caprock: First, the convective strip-shaped heat reservoir exposed by the hot springs on the peripheral fault zone of the basin; second, the underlying hot dry rock layered heat reservoir and the upper new generation heat reservoir and caprock in the basin revealed by drilling data. (4) Thermal system: Based on the characteristics of the “heat source-heat transfer-heat reservoir and caprock”, it is preliminarily believed that the Gonghe Basin belongs to the non-magmatic heat source hydrothermal geothermal system (type II21) and the dry heat geothermal system (type II22). Its favorable structural position and special geological evolutionary history have given birth to a unique environment for the formation of the geothermal system. There may be a cumulative effect of heat accumulation in the eastern part of the basin, which is expected to become a favorable exploration area for hot dry rocks. 相似文献
42.
青藏高原地热资源丰富,具有分布广、温度高、潜力大等特点。为了更好地评价该区地热资源潜力,探索符合青藏高原地热资源特点的勘查、开发方案,需要对地热资源分布规律及成因进行研究。在总结前人对青藏高原新生代岩浆活动和地热资源特征的基础上,从青藏高原地质演化的角度分析地热资源分布的控制因素,探讨新生代岩浆活动与地热资源的空间展布关系,重点讨论藏南地区地热区划和雅鲁藏布缝合带岩浆活动之间的关系。结果表明: 青藏高原地热活动受控于地质构造演化,具有南强北弱的分布特点; EW向区域性构造缝合带和SN向深大断裂的交汇部位是地热的主要活跃区域,不同的岩浆活动为地热提供热源。 相似文献
43.
In order to improve our understanding of microphysical properties of clouds and precipitation over the Tibetan Plateau (TP), six cloud and precipitation processes with different intensities during the Third Tibetan Plateau Atmospheric Science Experiment (TIPEX-Ⅲ) from 3 July to 25 July 2014 in Naqu region of the TP are investigated by using the high-resolution mesoscale Weather Research and Forecasting (WRF) model. The results show unique properties of summertime clouds and precipitation processes over the TP. The initiation process of clouds is closely associated with strong solar radiative heating in the daytime, and summertime clouds and precipitation show an obvious diurnal variation. Generally, convective clouds would transform into stratiform clouds with an obvious bright band and often produce strong rainfall in midnight. The maximum cloud top can reach more than 15 km above sea level and the velocity of updraft ranges from 10 to 40 m s-1. The simulations show high amount of supercooled water content primarily located between 0 and -20℃ layer in all the six cases. Ice crystals mainly form above the level of -20℃ and even appear above the level of -40℃ within strong convective clouds. Rainwater mostly appears below the melting layer, indicating that its formation mainly depends on the melting process of precipitable ice particles. Snow and graupel particles have the characteristics of high content and deep vertical distribution, showing that the ice phase process is very active in the development of clouds and precipitation. The conversion and formation of hydrometeors and precipitation over the plateau exhibit obvious characteristics. Surface precipitation is mainly formed by the melting of graupel particles. Although the warm cloud microphysical process has less direct contribution to the formation of surface precipitation, it is important for the formation of supercooled raindrops, which are essential for the formation of graupel embryos through heterogeneous freezing process. The growth of graupel particles mainly relies on the riming process with supercooled cloud water and aggregation of snow particles. 相似文献
44.
利用青海玉树隆宝地区2014年12月积雪升华过程的观测资料,分析了积雪升华过程中高寒湿地陆气相互作用特征及积雪深度对陆气相互作用的影响。结果表明:在降雪和积雪升华过程中,高寒湿地浅层土壤温度在短时期内有所升高,而深层土壤温度和土壤体积含水量对降雪过程的响应不敏感。积雪升华过程中净辐射、感热通量和潜热通量的日平均值增加,向上短波辐射的日平均值减少。积雪逐渐升华导致地表吸收的能量增加,同时地表向大气传递的能量也随之增加。随着积雪的逐步升华,感热占比和潜热占比逐渐升高,而土壤热通量占比和热储存占比逐渐降低。积雪深度增加会导致地表反照率和地表比辐射率增大,感热输送系数减小。 相似文献
45.
青藏高原东部表土磁化率特征与环境意义 总被引:2,自引:0,他引:2
现代表土磁化率与气候因子关系的研究是黄土古气候重建的重要内容,在黄土高原地区取得了重要进展,但在青藏高原地区相对不足。在青藏高原东部系统采集了106个表土样品,分析了其磁化率的变化特征;并通过表土磁化率与气候因子的相关分析,讨论了气候因子对高原东部现代表土低频磁化率和频率磁化率的影响。结果表明:研究区表土磁化率特征主要受到温度和降水量的影响,水热组合差异影响表土磁化率值的高低。低频磁化率与气候因子的相关性较弱,总体上与温度的相关性优于降水量,可能表明其与气候因子的关系比较复杂;频率磁化率百分比与降水呈较好的正相关关系,表明该指标对降水量的变化更为敏感,可以用于青藏高原东部的古降水定量重建。 相似文献
46.
以青藏高原长江源区典型高寒草地小流域为研究对象,基于2012年小流域气象监测数据和小流域径流水样分析,探讨了小流域水体碳氮输出特征,分析了气象因子和土壤水热对小流域水体碳氮输出的影响。结果表明,径流水体碳氮质量浓度均较低,其中可溶性有机碳(DOC)、可溶性有机氮(DON)、铵态氮(NH4+-N)和硝态氮(NO3--N)含量分别在2.95~6.96mg.L-1、0.45~1.15mg.L-1、0.02~0.88mg.L-1和0.16~0.36mg.L-1之间;DOC、DON、NO3--N在8~10月份之间随时间逐渐升高,9月中旬达到峰值后波动下降,NH4+-N无显著的季节变化特征,溶解氮中DONNO3--NNH4+-N;DOC和DON的输出量与降水、不同土层(20、40、60、90、120cm)地温和不同深度(10、20、40、60cm)土壤水分、水温呈极显著正相关(P0.001),与90、120cm土壤水分呈极显著负相关(P0.001);NH4+-N的输出量与降水、气温、水温呈显著正相关(P0.05);NO3--N与降水呈极显著正相关(P0.001)。 相似文献
47.
利用内蒙古及周边地区70个气象站1951~2014年降水数据,采用标准化降水指数等方法,对内蒙古近64年气候干旱时空变化进行分析。结果表明:研究区近64年来除西部年际、春、秋、冬季,中部春、秋季及东部春、冬季气候趋于湿润外,其他均趋于干旱。中、东部年际、植(作)物生长期SPI在2001年和1990年左右发生突变,东部突变后趋于干旱并在2006年左右又发生明显转折后趋于湿润。西部在1960s干旱严重,中、东部在1990s至2000s干旱严重。西部年际SPI由西北向东南、东部由南向北干旱趋势速率呈阶梯状下降,中部干旱趋势速率较西、东部快;植(作)物生长期SPI空间变化与年际一致,但西、中部干旱趋势明显的区域有所扩大。 相似文献
48.
基于主成分分析的青藏高原多年冻土区高寒草地土壤质量评价 总被引:5,自引:1,他引:4
土壤质量评价是提高对土壤质量理解的关键环节。为了了解青藏高原多年冻土区高寒草地土壤质量的基本情况,在青藏高原腹地西大滩至安多地区,根据不同海拔梯度和植被盖度共采集了154个土壤样品。通过主成分分析(PCA)法确定了影响青藏高原多年冻土区高寒草地土壤质量的最小数据集(MDS):全氮、全磷、全钾。根据影响土壤质量的最小数据集对青藏高原多年冻土区高寒草地土壤质量进行评价,得出了不同海拔、不同植被盖度下的土壤质量指数(SQI)。通过对不同海拔、不同植被盖度的土壤质量指数进行对比研究表明:随着海拔的升高,SQI呈增加的趋势,即海拔4 300~4 600 m(0.270±0.043) < 海拔4 600~4 900 m(0.326±0.061) < 海拔4 900~5 200 m(0.410±0.075);随着植被盖度的增加,SQI也呈现增加的变化趋势,即植被盖度小于50%(0.262~0.265) < 植被盖度大于50%(0.336~0.344)。在分别考虑了有机质、盐分、土壤水分对土壤质量的影响下得出的土壤质量指数值与基于最小数据集得到的土壤质量指数相一致,说明基于主成分分析的最小数据集可以对青藏高原多年冻土区高寒草地土壤质量做出较准确的评价。 相似文献
49.
曹四夭钼矿床位于华北克拉通北缘凉城断隆东侧,其矿化与多期次侵位的花岗质杂岩体具有密切的时间和空间联系。杂岩体的岩石类型包括:少斑状花岗斑岩、多斑状花岗斑岩、中细粒花岗岩、二长花岗斑岩和正长花岗斑岩等;前人的锆石U-Pb法测年数据表明,矿区岩浆活动可以分为155 Ma、149~140 Ma、134~131 Ma三个期次。本次研究获得矿区少斑状花岗斑岩的锆石LA-ICP-MS U-Pb法测年加权平均年龄为167Ma±1.2Ma,反映矿区可能还存在较早期的岩浆活动(中-晚侏罗世),其可与155 Ma岩浆岩划分为矿区早期的岩浆活动。花岗斑岩体具有高酸度、高钾和高铝质含量特征,总体属于酸性富钾钙碱性系列;花岗斑岩体含铝指数(A/CNK)介于1.20~2.49之间,Tb、Nd、Ga和LREE(Eu除外)富集,Eu、Ti、Sr、P亏损,属于高度分异的A型花岗岩系列。曹四夭花岗斑岩体形成于中-晚侏罗世构造机制转化时期,可能与蒙古-鄂霍次克洋闭合后的后造山伸展有关,为晚侏罗世钼多金属矿化的母岩。 相似文献
50.
This work restored the erosion thickness of the top surface of each Cretaceous formations penetrated by the typical well in the Hari sag, and simulated the subsidence burial history of this well with software BasinMod. It is firstly pointed out that the tectonic subsidence evolution of the Hari sag since the Cretaceous can be divided into four phases: initial subsidence phase, rapid subsidence phase,uplift and erosion phase, and stable slow subsidence phase. A detailed reconstruction of the tectonothermal evolution and hydrocarbon generation histories of typical well was undertaken using the EASY R_0% model, which is constrained by vitrinite reflectance(R_0) and homogenization temperatures of fluid inclusions. In the rapid subsidence phase, the peak period of hydrocarbon generation was reached at c.a.105.59 Ma with the increasing thermal evolution degree. A concomitant rapid increase in paleotemperatures occurred and reached a maximum geothermal gradient of about 43-45℃/km. The main hydrocarbon generation period ensued around 105.59-80.00 Ma and the greatest buried depth of the Hari sag was reached at c.a. 80.00 Ma, when the maximum paleo-temperature was over 180℃.Subsequently, the sag entered an uplift and erosion phase followed by a stable slow subsidence phase during which the temperature gradient, thermal evolution, and hydrocarbon generation decreased gradually. The hydrocarbon accumulation period was discussed based on homogenization temperatures of inclusions and it is believed that two periods of rapid hydrocarbon accumulation events occurred during the Cretaceous rapid subsidence phase. The first accumulation period observed in the Bayingebi Formation(K_1 b) occurred primarily around 105.59-103.50 Ma with temperatures of 125-150℃. The second accumulation period observed in the Suhongtu Formation(K_1 s) occurred primarily around84.00-80.00 Ma with temperatures of 120-130℃. The second is the major accumulation period, and the accumulation mainly occurred in the Late Cretaceous. The hydrocarbon accumulation process was comprehensively controlled by tectono-thermal evolution and hydrocarbon generation history. During the rapid subsidence phase, the paleo temperature and geothermal gradient increased rapidly and resulted in increasing thermal evolution extending into the peak period of hydrocarbon generation,which is the key reason for hydrocarbon filling and accumulation. 相似文献