全文获取类型
| 收费全文 | 122篇 |
| 免费 | 16篇 |
| 国内免费 | 30篇 |
专业分类
| 大气科学 | 1篇 |
| 地球物理 | 7篇 |
| 地质学 | 143篇 |
| 海洋学 | 13篇 |
| 综合类 | 1篇 |
| 自然地理 | 3篇 |
出版年
| 2023年 | 3篇 |
| 2022年 | 3篇 |
| 2021年 | 3篇 |
| 2020年 | 4篇 |
| 2019年 | 3篇 |
| 2018年 | 1篇 |
| 2017年 | 8篇 |
| 2016年 | 4篇 |
| 2015年 | 8篇 |
| 2014年 | 8篇 |
| 2013年 | 7篇 |
| 2012年 | 9篇 |
| 2011年 | 10篇 |
| 2010年 | 6篇 |
| 2009年 | 5篇 |
| 2008年 | 8篇 |
| 2007年 | 13篇 |
| 2006年 | 7篇 |
| 2005年 | 11篇 |
| 2004年 | 9篇 |
| 2003年 | 7篇 |
| 2002年 | 4篇 |
| 2001年 | 4篇 |
| 2000年 | 9篇 |
| 1999年 | 2篇 |
| 1998年 | 1篇 |
| 1997年 | 1篇 |
| 1996年 | 4篇 |
| 1995年 | 4篇 |
| 1994年 | 1篇 |
| 1993年 | 1篇 |
排序方式: 共有168条查询结果,搜索用时 31 毫秒
1.
东营凹陷牛庄洼陷沙河街组发育有超压系统,这对油气运移和聚集过程有着重要的影响。在对超压系统现今发育特征研究的基础上,本文运用约束下数值模拟方法对牛庄洼陷超压系统的演化规律进行研究,并探讨了超压系统的主要形成机制。牛庄洼陷在沙河街组四段、沙河街组三段的下亚段和中亚段存在着超压系统,最大压力系数可以达到1.8,最大剩余压力超过了20MPa。自沙三段上亚段沉积期开始,超压系统开始发育。到东营组沉积期末,超压系统经历了大约10Ma的泄压过程。自新近系馆陶组沉积期,超压系统再次迅速增压,逐渐接近现今发育状况。上覆地层沙三段上亚段高沉积速率导致了超压系统的形成和早期剩余压力的增加,而水热增压和烃类物质大量生成联合造成超压系统晚期迅速增压。超压系统演化规律揭示出在油气主要运移期研究区古异常流体压力的分布状况,这为进一步开展牛庄洼陷油气运移和聚集过程的动力学研究提供了理论依据。 相似文献
2.
三肇凹陷青山口组源岩生成油向下“倒灌”运移层位及其研究意义 总被引:14,自引:1,他引:13
为了研究三肇凹陷青山口组源岩生成的油向下“倒灌”运移层位,对油向下“倒灌”运移机制及条件进行了研究,得到三肇凹陷扶杨油层同时具备①青山口组源岩目前应具有足够大的超压;②存在连通青山口组源岩和扶杨油层的T2断裂2个条件,青山口组源岩生成的油能够在超压的作用下在嫩江组沉积末期、明水组沉积末期和古近系沉积末期通过T2断裂向下伏扶杨油层中“倒灌”运移。利用压力封闭原理,对三肇凹陷青山口组源岩生成的油向下“倒灌”运移距离进行了研究,得到三肇凹陷青山口组源岩生成的油向下“倒灌”运移距离一般大于500 m,而三肇凹陷扶杨油层地层厚度最大只有500 m,表明三肇凹陷青山口组源岩生成的油可以向下“倒灌”运移至整个扶杨油层的任何部位。目前三肇凹陷扶杨油层从上至下均含油,且已找到的油藏均分布于青山口组源岩生成的油能够向下“倒灌”运移分布范围内或附近,这表明青山口组源岩生成的油向下“倒灌”运移层位控制着油气富集层位,青山口组源岩生成的油向下“倒灌”运移分布范围控制着三肇凹陷扶杨油层油藏形成与分布范围。青山口组源岩生成的油向下“倒灌”运移分布范围及其附近应是三肇凹陷扶杨油层油下一步勘探的有利地区。 相似文献
3.
4.
辽河盆地大民屯凹陷流体压力特征 总被引:1,自引:0,他引:1
大民屯凹陷是辽河断陷内4个下第三系凹陷之一。在综合利用钻井、试井及地震等资料的基础上,系统研究并论述了大民屯凹陷流体压力特征。基于57口井的声波测井资料,凹陷内泥岩压力特征可区分为正常压力、异常压力或强超压等类型;根据152口井391个点的压力测试数据,凹陷内产油层段的压力梯度多接近于1;利用公式法模拟计算了47条地震剖面的流体压力、剩余压力及压力系数的分布特征,凹陷内剖面压力系统自上而下一般由正常压力、弱超压和强超压3部分组成。此外,还根据流体压力演化的基本原理及钻井、岩性与试井等实际资料,模拟恢复了大民屯凹陷的压力演化史,其可划分为超压原始积累、超压部分释放及超压再积聚3个阶段。总体上,大民屯凹陷的超压强度低于渤海湾盆地其他地区的超压强度。 相似文献
5.
Xiaorong Luo 《Earth and Planetary Science Letters》2002,201(2):431-446
Natural hydrofracturing caused by overpressure plays an important role in geopressure evolution and hydrocarbon migration in petroliferous basins. Its mechanism is quite well understood in the case of artificial hydraulic fracturing triggered by high-pressure fluid injection in a well. This is not so for natural hydraulic fracturing which is assumed to initiate as micro-cracks with large influence on the permeability of the medium. The mechanism of natural hydraulic cracking, triggered by increasing pore pressure during geological periods, is studied using a fracturing model coupled to the physical processes occurring during basin evolution. In this model, the hydraulic cracking threshold is assumed to lie between the classical failure limit and the beginning of dilatancy. Fluid pressure evolution is calculated iteratively in order to allow dynamic adjustment of permeability so that the fracturing limit is always preserved. The increase of permeability is interpreted on the basis of equivalent fractures. It is found that fracturing is very efficient to keep a stress level at the rock’s hydraulic cracking limit: a fracture permeability one order of magnitude larger than the intrinsic permeability of the rock would be enough. Observations reported from actual basins and model results strongly suggest that natural hydraulic cracking occurs continuously to keep the pressure at the fracturing limit under relaxed stress conditions. 相似文献
6.
HAO Fang JIANG Jianqun ZOU Huayao FANG Yong & ZENG Zhiping . Key Lab for Hydrocarbon Accumulation Mechanism in the Ministry of Education Petroleum University Beijing China . Department of Petroleum Geology China University of Geosciences Wuhan China 《中国科学D辑(英文版)》2004,47(9)
Thetraditionalhydrocarbongenerationmodeldoesnottakeintoaccounttheeffectofpressure[1].Astotheroleofpressureinorganicmattermaturationandpetroleumgeneration,threeconflictingopinionshaveeverbeenproposed:(1)Increasingpressurehasnodetectableeffectonorganic-mattermaturation[1,2];(2)increasingpressureenhanceshydrocarbon-thermaldestruction[3];(3)increasingpressuresignificantlyretardsorganic-mattermaturationandhydrocarbongeneration[4,5].Therearemorethan180overpressuredbasinsintheworld.Theroleofoverpress… 相似文献
7.
8.
Xue‐Bin Du Xi‐Nong Xie Yong‐Chao Lu Liang Zhang Wei Peng Yun‐Peng Li 《Geological Journal》2015,50(4):465-476
Pressure measurements using drill stem tests and estimates from log data calculation indicate that three vertically stacked regional pressure compartments exist in the Qikou Depression of Bohai Bay Basin, N. China. The compartments comprise hydrostatic, upper weak, and lower overpressure systems. Laterally, overpressure (pressure coefficient > 1.2) occurs in the deeper areas and weakens gradually from the centre to the margin of the depression. The accumulation of oil and gas exhibits the interesting characteristics of oil‐bearing layers above gas‐bearing layers in the Qikou Depression. The pattern can be accounted for by the evolution of overpressure system, the maturity process of the source rock and the main fault activity. In the late Dongying Formation (Ed, 30 Ma), the lower overpressure system began to form shape, and the hydrocarbon sources generated a large volume of oil. However, because there was no migration pathway, the oil only accumulated in the original strata. In the late Guantao Formation (Ng, 12 Ma), the gas was generated, the upper overpressure system formed gradually, and the activity of the main fault gradually increased. Then, the overpressure pushed the early gathered oil to flow from the lower overpressure system into the upper overpressure system. Afterwards, the activity of the main fault decreased again and remains weak until now. Thus, later generated natural gas cannot keep migrating along the main fault and can only accumulate in the lower overpressure system. Copyright © 2014 John Wiley & Sons, Ltd. 相似文献
9.
The distribution and genetic mechanisms of abnormal pressures in the Bohai Bay Basin were systematically analyzed. Abnormal pressures are widely developed in the Bohai Bay Basin, primarily in the Paleogene E2s4, E2s3, Es1, and Ed formations. From the onshore area of the Bohai Bay Basin to the center of the Bozhong area, the top depth of the overpressured zone in each depression increases gradually, the overpressured strata in each depression gradually move to younger formations, and the pressure structure successively alters from single-bottom- overpressure to double-bottom-overpressure and finally to double-top-overpressure. The distribution of overpressured area is consistent with the sedimentary migration controlled by the tectonic evolution of the Bohai Bay Basin, which is closely related to the hydrocarbon-generation capability of active source rocks. The overpressured strata are consistent with the source-rock intervals in each depression; the top of the overpressured zone is synchronous with the hydrocarbon generation threshold in each depression; the hydrocarbon generation capability is positively correlated with the overpressure magnitude in each formation. Undercompaction was the main mechanism of overpressure for depressions with fluid pressure coefficients less than 1.2, whereas hydrocarbon generation was the main mechanism for depressions with fluid pressure coefficients greater than 1.5. 相似文献
10.
川西坳陷新场构造带须家河组超压演化与流体的关系 总被引:1,自引:0,他引:1
沉积盆地超压体系是油气勘探与开发过程中一个不容忽视的问题,不仅影响了地质流体的运移和聚集,更为勘探带来安全隐患。以实测地压和油田水化学数据为基础,对川西坳陷新场构造带须四段和须二段现今地层水矿化度与现今压力系数关系进行比较,结合地层水特征系数和阴阳离子关系,综合前人研究结果,对须四段和须二段压力演化史与地层水演化过程进行分析,考察川西坳陷须家河组超压系统演化与地层水演化的耦合关系。结果表明,须家河组超压发育与地层水具有密切的联系:(1)须家河组储层段压力分布范围较广,在弱超压至超强压之间,须二段属于中超压而须四段属于超高压,平面分布中须二段探测井中矿化度随压力系数增加而减少,须四段则相反;(2)在压实过程中,由于流体排驱受阻导致"欠压实"超压的产生,随着超压的不断积聚,局部出现裂缝,导致地层水更加强烈的混合作用和运移;(3)生烃作用导致自生压力增大,地层水离子水岩作用强烈,造成流体包裹体与现今地层水离子成分分异;(4)构造挤压抬升过程中,须四段裂缝不发育,压力进一步升高,须二段则产生泄压,出现了凝析水和水侵现象,造成须四段和须二段现今地层水特征的差异。 相似文献