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推动地球板块运动的力可以分为内部力源和外部力源,只有外部力源才会使地球板块产生持续的同向运动。在对历史地质资料总结的基础上,得出银河年周期对地球板块的运动有重大影响。可以认为全球板块聚合一离散周期以银河年为周期。全球板块大约在一个银河年内(220-250Ma)离散一聚合一次。在比较现代科学技术手段对地球板块运动的监测结果和地球受到的太阳、月亮固体潮的理论计算结果基础上,得出结论:太阳、月亮对地球的固体潮力是推动地球板块日常运动的重要外部力源。除此之外,自转的影响也是使板块运动的力源。 相似文献
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全地幔对流因地球自转而具十二个规律性分布的旋涡单元,全球岩石圈因此表现出明显的旋涡构造特征。地球的演化与太阳系在银河系中的运动规律有关,周期性的银河天体撞击使规律性的全球旋涡构造受到银河年周期的撞击破坏。地球的构造发展表现为:旋涡运动—撞击破坏—旋涡恢复,周而复始,逐步演进。运用这个新假说,本文将全球海沟划分为五种成因四种类型,将全球大陆地台的活化也分成了五种成因类型。 相似文献
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文章简要地回顾了科学大洋钻探的发展历程。深海钻探计划革命性地改变了地球科学家们对地球动力作用的认识。DSDP的后继者,即大洋钻探计划正在全球各大洋收集有关这些作用在几万至几十万年时间尺度上变化的高分辨率记录,并已在与全球气候有关的下述领域取得了重要进展:地质历史时期气候变化的幅度,速度及原因,按轨道调谐的新生代地质年代表,高纬度地区冰盖形成及演化历史,造山运动与长期气候变化之间的相互关系,气体水合 相似文献
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古—中生代之交的全球变化与生物效应 总被引:9,自引:0,他引:9
古—中生代之交是显生宙以来最大的一次生物绝灭期 ,其形成机制一直是地学界长期探讨的热点课题之一。地史重大转折期是地球内、外各圈层长期作用下 ,各种量变达到阀值 ,加之可能的外因激化 ,在短时间内以连锁反应形式相继质变 ,形成了全球变化 (包括生物绝灭 )的地球突变期。文中从可能的外因 (外星体撞击事件 )及内因 (岩石圈的变化 ,地球表层的变化和生物圈的变化 )两个方面探讨了古—中生代之交的全球变化与生物效应 相似文献
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旋回地层学和天文年代学及其在中生代的研究现状 总被引:1,自引:0,他引:1
地质年代的精确确定是我们认识地球演化历史和过程的关键,而如何提高地质年代的精度却一直是个尚待解决的科学难题。最近30年多年来,基于古气候学研究的天文旋回理论获得了普遍认可和广泛应用,尤其是成功应用于天文地质年代校准中。这种数字定年方法是通过天文调谐获得连续的高分辨率的地质年代,是对传统地质定年方法如古生物、古地磁以及放射性同位素测年方法的一次革新。最新的国际地质年表The Geologic Time Scale 2012(简称GTS2012)中经过天文校准的地质年代已近100%覆盖了新生代,而中生代的天文年代校准还存在着很大挑战。目前应用稳定的405 ka的偏心率长周期对中生代地层进行天文地质年代校准,是国际地质年表从GTS2004到GTS2012的一个最大改进。文中将主要介绍天文旋回的基础理论和其在中生代的应用及其研究现状。 相似文献
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地球系统科学不应当理解为各门地球科学的叠加,而是探索其圈层相互作用,整合其各种学科,将地球作为一个完整系统来研究的学问。地球系统科学从全球变化开始,然后向早期的地质年代推进。而当前面临的新任务是将地球表层与地球内部过程连接起来研究。 相似文献
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地史时期古气候的宏观演化和现代气候的变化具有一些重大的不同之处:1.在亿年的时间尺度上,全球古气候的分带产生了变异性;2.在同样的时间尺度上,全球古气候的分带出现了非对称性;3.就地球整个历史时期冷、热阶段的交替出现,不同的时间尺度,具有不同的调控因素所造成的周期,超越了米兰柯维奇(Milankovitch,1941)的天文气候理论。应该从不同层次的天地因素-银河系、太阳系和地球运动系统中去寻找更深层次的相关因素。 相似文献
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在解译地震测量数据的基础上,推测地球中心不是一个地核,而是存在两个固态的“亚核”。在旋转体制影响下它们相互作用,这就需要重新研究在液核中对流的原因和与其相关的磁场倒转。研究了地球全球构造不对称性的原因和铀矿省在行星空间分布的不均一性,在考虑大西洋半球和太平洋半球不同构造格局的情况下,将全球成矿时代和泛大陆的形成和分解的周期相联系,确定了产铀最好的时代与地球从远银河向近银河过渡时旋转条件的变化相关。在这种情况下与铀成矿有关的最主要的形变类型不是褶皱形变,而是断块形变,主要为穹隆-断块型形变。 相似文献
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科学大洋钻探与全球气候变化研究 总被引:2,自引:0,他引:2
文章简要地回顾了科学大洋钻探的发展历程。深海钻探计划(DSDP)革命性地改变了地球科学家们对地球动力作用的认识。DSDP的后继者,即大洋钻探计划(ODP)正在全球各大洋收集有关这些作用在几万至几十万年时间尺度上变化的高分辨率记录,并已在与全球气候有关的下述领域取得了重要进展:地质历史时期气候变化的幅度、速度及原因,按轨道调谐的新生代(10Ma前以来)地质年代表,高纬度地区冰盖形成及演化历史,造山运动与长期气候变化之间的相互关系,气体水合物与全球气候变化的相互制约关系。DSDP和ODP的成就使地球科学家们相信,在全球年轻的大洋底实施钻探以取得连续的沉积记录和录井记录,是研究过去全球气候的长期、短期变化的有效而重要的手段,并将给未来全球变化的研究带来启示 相似文献
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The geological record provides an irreplaceable account of the joint history between the Earth and living organisms. Extant living organisms also contain in their phenotypes and most importantly in their genomes information about their history, and about the history of the Earth. In this review we explain how biologists attempt to extract this information and draw inferences about past history, using statistics, computer algorithms, and molecular biology. We show that inferred ancestral gene contents provide insights into ancient metabolisms, ancestral genome composition in bases or amino-acids provide information about ancient growth temperatures, and protein resurrection offers means to investigate the function of proteins long disappeared. All these inferences throw a new light on organism and Earth evolution. Their combination and the use of statistical models integrating both genomic and geologic histories hold great promises for unveiling more of the past 4 billion year history on Earth. 相似文献
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Johann Steiner 《Australian Journal of Earth Sciences》2013,60(1):99-131
Present‐day galactic data permit the construction of a galactic model in which the galactic gravitational field is described by a gravitational function rather than the Newtonian gravitational “constant” G. The concept of this empirical gravitational function, which is based on galactic orbital velocity data, envisages G as a function of time and space. In this model the interaction of this gravitational function, which has rotational symmetry in the galactic plane, and the slightly elliptical galactic orbit of the solar system results in a systematic variation of G. This interaction specifies a simple galactic time‐scale which can be conveniently compared with events of the geological time‐scale. For reasons of galactic evolution and modifying effects due to suspected changes of mass distributions in the universe with the passage of time, which are classed here under the Dirac‐Jordan Effect, such a comparison is initially restricted to the past 1#fr1/4> cosmic years, or 350 million years. The problems in extending such a comparison to 8 cosmic years are discussed, and such an extension seems promising, but it is hampered by the paucity of geological and geophysical data from the lower Palaeozoic and the Precambrian and the present uncertainties in regard to galactic evolution. “Worldwide” statistical maxima and minima of the following geological criteria disclose an episodic correlation with the variation of G and the rates of change of G during the past 350 million years, as specified by this galactic model. It is possible to interpret this correlation in terms of accepted geological principles and concepts in most cases. The following geological phenomena are considered in this comparison of the galactic and geological time‐scales for the past 350 million years.
Period boundaries of the stratigraphic system 相似文献
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周期性是宇宙一切事物运动发展的普遍现象。从宏观空间--天体的运动,如银河系的旋转,太阳黑子的活动;到微观世界--基本粒子的运动,相同或类似现象在时间上莫不具有循环往复的特点。各种物质运动形式的周期性已逐渐地越来越多地为人们所认识,从昼夜的交替及四季的递变认识到地球自转与公转的周期,通过天文观测又进一步认识了日、月蚀出现的周期及其他一些天体运动的周期。 相似文献
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A New Progress of the Proterozoic Chronostratigraphical Division 总被引:1,自引:0,他引:1
The Precambrian, an informal chronostratigraphical unit, represents the period of Earth history from the start of the Cambrian at ca. 541 Ma back to the formation of the planet at 4567 Ma. It was originally conceptualized as a "Cryptozoic Eon" that was contrasted with the Phanerozoic Eon from the Cambrian to the Quaternary, which is now known as the Precambrian and can be subdivided into three eons, i.e., the Hadean, the Archean and the Proterozoic. The Precambrian is currently divided chronometrically into convenient boundaries, including for the establishment of the Proterozoic periods that were chosen to reflect large-scale tectonic or sedimentary features(except for the Ediacaran Period). This chronometric arrangement might represent the second progress on the study of chronostratigraphy of the Precambrian after its separation from the Phanerozoic. Upon further study of the evolutionary history of the Precambrian Earth, applying new geodynamic and geobiological knowledge and information, a revised division of Precambrian time has led to the third conceptual progress on the study of Precambrian chronostratigraphy. In the current scheme, the Proterozoic Eon began at 2500 Ma, which is the approximate time by which most granite-greenstone crust had formed, and can be subdivided into ten periods of typically 200 Ma duration grouped into three eras(except for the Ediacaran Period). Within this current scheme, the Ediacaran Period was ratified in 2004, the first period-level addition to the geologic time scale in more than a century, an important advancement in stratigraphy. There are two main problems in the current scheme of Proterozoic chronostratigraphical division:(1) the definition of the Archean–Proterozoic boundary at 2500 Ma, which does not reflect a unique time of synchronous global change in tectonic style and does not correspond with a major change in lithology;(2) the round number subdivision of the Proterozoic into several periods based on broad orogenic characteristics, which has not met with requests on the concept of modern stratigraphy, except for the Ediacaran Period. In the revised chronostratigraphic scheme for the Proterozoic, the Archean–Proterozoic boundary is placed at the major change from a reducing early Earth to a cooler, more modern Earth characterized by the supercontinent cycle, a major change that occurred at ca. 2420 Ma. Thus, a revised Proterozoic Eon(2420–542 Ma) is envisaged to extend from the Archean–Proterozoic boundary at ca. 2420 Ma to the end of the Ediacaran Period, i.e., a period marked by the progressive rise in atmospheric oxygen, supercontinent cyclicity, and the evolution of more complex(eukaryotic) life. As with the current Proterozoic Eon, a revised Proterozoic Eon based on chronostratigraphy is envisaged to consist of three eras(Paleoproterozoic, Mesoproterozoic, and Neoproterozoic), but the boundary ages for these divisions differ from their current ages and their subdivisions into periods would also differ from current practice. A scheme is proposed for the chronostratigraphic division of the Proterozoic, based principally on geodynamic and geobiological events and their expressions in the stratigraphic record. Importantly, this revision of the Proterozoic time scale will be of significant benefit to the community as a whole and will help to drive new research that will unveil new information about the history of our planet, since the Proterozoic is a significant connecting link between the preceding Precambrian and the following Phanerozoic. 相似文献
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关于全球变化研究的几个问题 总被引:2,自引:0,他引:2
第四纪地质工作者面临全球变化研究的形势,应主动调整自身的研究战略,注重最近0.15Ma环境信息的提取,加强地质过程的研究,重视人类活动对环境的影响,强调模型的模拟和检验。 相似文献
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Radan Květ 《GeoJournal》1991,24(4):417-420
Conclusion The proposal for a new complete classification of the Earth's evolution in accordance with periods of geotectonic cycles — depending on the external cosmic influence of the galactic year — has been elaborated as an additional application of a system model. Its basic idea is the principle of a hierarchical division and recurring cycles. For the time being, the significance of a periodical time table is a theoretical one. It allows a new view to be used when evaluating the last stages of the Earth's history during the Phanerozoic for which comparatively more geological information is available. However, a universal approach like the one described above can aid in directing further research on the older history of the Earth. Later on, theoretical knowledge could be applied to economic geology, above all if using a hierarchical classification of the phases of geotectonic cycles. 相似文献
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The null hypothesis: globally steady rates of erosion,weathering fluxes and shelf sediment accumulation during Late Cenozoic mountain uplift and glaciation 总被引:1,自引:0,他引:1 
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下载免费PDF全文 At the largest time and space scales, the pace of erosion and chemical weathering is determined by tectonic uplift rates. Deviations from equilibrium arise from the transient response of landscape denudation to climatic and tectonic perturbations. We posit that the constraint of mass balance, however, makes it unlikely that such disequilibrium persists at the global scale over millions of years, as has been proposed for late Cenozoic erosion. We synthesize weathering fluxes, global sedimentation rates, sediment yields and tectonic motions to show a remarkable constancy in the pace of Earth‐surface evolution over the last 10 Ma and support the null hypothesis – that global rates of landscape change have remained constant over this time period, despite global climate change and mountain building events. This work undermines the hypothesis that increased weathering due to mountain building or climate change was the primary agent for a decrease in global temperatures. 相似文献
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全球板块构造的动力学机制问题是一个热门但至今尚未解决的难题。本文首先回顾了近百年来大地构造学的各种主要假说和近四十年来板块构造学说的许多新进展。在上述研究的基础上, 受Rampino和Stothers关于陨击作用可引起地表重大灾变事件思想的启发,笔者提出了一个新的假说。基于中、新生代(200 Ma以来)每隔33 Ma太阳系就会穿越一次银河系星际物质密集的银道面,诱发太阳系内部引力场的巨变,使部分小行星失稳,从而撞击地球。笔者根据用以描述中生代以来全球板块构造的七种不同的运动模式, 提出了巨大陨星在不同地点、以不同角度撞击地表岩石圈,可能诱发地幔底辟的形成,从而推动板块呈放射状或单向运移的假说,也即在200、170、100、65和0.78 Ma等时期的陨击事件基本上是垂直地表面而撞击的,从而诱发地幔底辟的形成和岩石圈板块的放射状张裂和运移;138 Ma的陨击事件可能是指向印度板块的斜向撞击;而35 Ma时期的微玻璃陨石撞击事件则是陨石以极低角度撞击地球表面的表现。陨石撞击地球,这是太阳系内部各星体之间引力作用变化的表现,因而此假说不是什么外因作用论。 相似文献