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1.
W. W. Hay 《International Journal of Earth Sciences》1996,85(3):409-437
Tectonics and climate are both directly and indirectly related. The direct connection is between uplift, atmospheric circulation, and the hydrologic cycle. The indirect links are via subduction, volcanism, the introduction of gasses into the atmosphere, and through erosion and consumption of atmospheric gases by chemical weathering. Rifting of continental blocks involves broad upwarping followed by subsidence of a central valley and uplift of marginal shoulders. The result is an evolving regional climate which has been repeated many times in the Phanerozoic: first a vapor-trapping arch, followed by a rift valley with fresh-water lakes, culminating in an arid rift bordered by mountains intercepting incoming precipitation. Convergence tectonics affects climate on a larger scale. A mountain range is a barrier to atmospheric circulation, especially if perpendicular to the circulation. It also traps water vapor converting latent to sensible heat. Broad uplift results in a shorter path for both incoming and outgoing radiation resulting in seasonal climate extremes with reversals of atmospheric pressure and enhanced monsoonal circulation. Volcanism affects climate by introducing ash and aerosols into the atmosphere, but unless these are injected into the stratosphere, they have little effect. Stratospheric injection is most likely to occur at high latitudes, where the thickness of the troposphere is minimal. Volcanoes introduce CO2, a greenhouse gas, into the atmosphere. Geochemical effects of tectonic uplift and unroofing relate to the weathering of silicate rocks, the means by which CO2 is removed from the atmosphere-ocean system on long-term time scales. 相似文献
2.
O. Averbuch N. Tribovillard X. Devleeschouwer L. Riquier B. Mistiaen B. van Vliet-Lanoe 《地学学报》2005,17(1):25-34
The Late Devonian was a period of drastic environmental changes, as exemplified by a major biotic crisis at the Frasnian–Famennian boundary (FFB) and the onset in Famennian times of glaciations across southern Gondwana. Worldwide evidence for the coeval development of the major Acadian–Eovariscan belt led us to propose a model relating the Late Frasnian–Famennian environmental perturbations to extensive continental uplift through two atmospheric CO2-depleting mechanisms: (1) the intensification of silicate weathering on the continental areas as attested by a major rise in the 87Sr/86Sr composition of sea water at the FFB; and (2) the massive burial of organic carbon (Kellwasser events) in partially confined basins due to the collisional-induced reduction of equatorial oceanic communications between the Palaeotethysian and Panthalassic oceans. This process is also suggested to have been controlled by an important primary productivity connected to an increased nutrient availability triggered by the enhanced continental run-off. 相似文献
3.
The geochemical composition of the terrestrial surface (without soils) and comparison with the upper continental crust 总被引:1,自引:0,他引:1
Jens Hartmann Hans H. Dürr Nils Moosdorf Michel Meybeck Stephan Kempe 《International Journal of Earth Sciences》2012,101(1):365-376
The terrestrial surface, the “skin of the earth”, is an important interface for global (geochemical) material fluxes between
major reservoirs of the Earth system: continental and oceanic crust, ocean and atmosphere. Because of a lack in knowledge
of the geochemical composition of the terrestrial surface, it is not well understood how the geochemical evolution of the
Earth’s crust is impacted by its properties. Therefore, here a first estimate of the geochemical composition of the terrestrial
surface is provided, which can be used for further analysis. The geochemical average compositions of distinct lithological
classes are calculated based on a literature review and applied to a global lithological map. Comparison with the bulk composition
of the upper continental crust shows that the geochemical composition of the terrestrial surface (below the soil horizons)
is significantly different from the assumed average of the upper continental crust. Specifically, the elements Ca, S, C, Cl
and Mg are enriched at the terrestrial surface, while Na is depleted (and probably K). Analysis of these results provide further
evidence that chemical weathering, chemical alteration of minerals in marine settings, biogeochemical processes (e.g. sulphate
reduction in sediments and biomineralization) and evaporite deposition are important for the geochemical composition of the
terrestrial surface on geological time scales. The movement of significant amounts of carbonate to the terrestrial surface
is identified as the major process for observed Ca-differences. Because abrupt and significant changes of the carbonate abundance
on the terrestrial surface are likely influencing CO2-consumption rates by chemical weathering on geological time scales and thus the carbon cycle, refined, spatially resolved
analysis is suggested. This should include the recognition of the geochemical composition of the shelf areas, now being below
sea level. 相似文献
4.
Grant M.Young 《地学前缘(英文版)》2013,4(3):247-261
In more than 4 Ga of geological evolution, the Earth has twice gone through extreme climatic perturbations, when extensive glaciations occurred, together with alternating warm periods which were accompanied by atmospheric oxygenation. The younger of these two episodes of climatic oscillation preceded the Cambrian “explosion” of metazoan life forms, but similar extreme climatic conditions existed between about 2.4 and 2.2 Ga. Over long time periods, changing solar luminosity and mantle temperatures have played important roles in regulating Earth's climate but both periods of climatic upheaval are associated with supercontinents. Enhanced weathering on the orogenically and thermally buoyed supercontinents would have stripped CO2 from the atmosphere, initiating a cooling trend that resulted in continental glaciation. Ice cover prevented weathering so that CO2 built up once more, causing collapse of the ice sheets and ushering in a warm climatic episode. This negative feedback loop provides a plausible explanation for multiple glaciations of the Early and Late Proterozoic, and their intimate association with sedimentary rocks formed in warm climates. Between each glacial cycle nutrients were flushed into world oceans, stimulating photosynthetic activity and causing oxygenation of the atmosphere. Accommodation for many ancient glacial deposits was provided by rifting but escape from the climatic cycle was predicated on break-up of the supercontinent, when flooded continental margins had a moderating influence on weathering. The geochemistry of Neoproterozoic cap carbonates carries a strong hydrothermal signal, suggesting that they precipitated from deep sea waters, overturned and spilled onto continental shelves at the termination of glaciations. Paleoproterozoic (Huronian) carbonates of the Espanola Formation were probably formed as a result of ponding and evaporation in a hydrothermally influenced, restricted rift setting. Why did metazoan evolution not take off after the Great Oxidation Event of the Paleoproterozoic? The answer may lie in the huge scar left by the ~2023 Ma Vredefort impact in South Africa, and in the worldwide organic carbon-rich deposits of the Shunga Event, attesting to the near-extirpation of life and possible radical alteration of the course of Earth history. 相似文献
5.
Climate‐modulated sequence development in a tropical rift basin during the Late Palaeocene to Early Eocene super greenhouse Earth 
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下载免费PDF全文 Sequence developments in rift basins are considered to be influenced largely by tectonics and to a lesser extent by eustatic sea‐level and climate. Studies indicate that in passive margin basins, climate can mask the effects of tectonics and eustasy by modulating the sediment supply. It is, however, less understood how the sedimentary sequence in rift basins might respond to strong climatic fluctuations where tectonic pulses generate rapid accommodation space. Here a case study has been provided to assess the effect of climate vis à vis sea‐level and tectonics on sequence development in the Cambay rift basin, western India, during the Early Palaeogene (Late Palaeocene to Early Eocene) super greenhouse globe. Facies analysis of this shale–lignite sequence suggests deposition in a lagoon/bay, developed over the Deccan Trap basement. Detailed sequence stratigraphic analysis using basin‐wide representative composite sections, marker lignite seam, event bed and high‐resolution carbon isotope (δ13C) chemostratigraphy suggest an overall transgressive motif. Among the three prominent Early Eocene eustatic highstands, only the one at ca 53·7 Ma is expressed by the thickest coal accumulation throughout the basin. Expression of the other sequence stratigraphic surfaces is subdued and can be due to the overall finer grain size of the sediment or local variation in the subsidence rate at different fault‐controlled mini‐basins. Enigmatic presence of a maximum flooding surface coinciding with the 53·7 Ma climate event (Eocene Thermal Maximum 2), manifested by negative carbon isotope excursion, indicates possible influence of climate over and above tectonics in developing the rift sequence. Qualitative rainfall variation assessed using the magnitude of the carbon isotope excursion and pollen abundance show that a relatively dry/low precipitation climatic phase during the Eocene Thermal Maximum 2 hindered the siliclastic supply to the basin. Thus, it has been inferred that climate‐induced high siliciclastic supply possibly enhanced the autocyclic reorganization and hindered the development of the key sequence stratigraphic surfaces across the basin during climate extremes. 相似文献
6.
A. V. Maslov V. N. Podkovyrov E. Z. Gareev O. V. Graunov 《Lithology and Mineral Resources》2016,51(2):117-135
The climatic impact on the formation of fine-grained rocks from the Riphean stratotype and Vendian Asha Group on the western slope of the South Urals during the time interval lasting approximately 1200 Ma is considered. It is shown that these rocks are largely represented by “tectonosilicate-dominated” shales. This feature combined with changes in the average K2O/Al2O3 values disavows the hypothesis in (Kennedy et al., 2006), according to which the growth of free oxygen concentration in the Late Riphean and Vendian atmosphere was determined by gradual intensification of the organic carbon extraction from the biosphere by clays. The average values of the hydrolyzate module, chemical index of alteration (CIA), and several lithogeochemical parameters calculated for the Riphean and Vendian clayey rocks provide grounds for the conclusion that intensity of weathering in paleodrainage areas during the accumulation of the Upper Precambrian sedimentary successions was low. The curve reflecting changes of the average CIA values in the Upper Precambrian fine-grained siliciclastic rocks of the South Urals is similar to some extent with the “standard” CIAcorrect. curve (GonzalezAlvarez and Kerrich, 2012). It is assumed that changes in microand macrobiotic communities during the Late Precambrian were controlled to a variable extent by climate fluctuations as well. At the same time, these fluctuations most likely left the chemical composition of water in the ocean virtually unchanged, which is evident from analysis of the redox conditions in the ocean and the distribution of primary producers with the average CIAcorrect. and CIA values. 相似文献
7.
Rivers, chemical weathering and Earth's climate 总被引:4,自引:0,他引:4
Bernard Dupr Cline Dessert Priscia Oliva Yves Goddris Jrme Viers Louis Franois Romain Millot Jrme Gaillardet 《Comptes Rendus Geoscience》2003,335(16):1141-1160
We detail the results of recent studies describing and quantifying the large-scale chemical weathering of the main types of continental silicate rocks: granites and basalts. These studies aim at establishing chemical weathering laws for these two lithologies, describing the dependence of chemical weathering on environmental parameters, such as climate and mechanical erosion. As shown within this contribution, such mathematical laws are of primary importance for numerical models calculating the evolution of the partial pressure of atmospheric CO2 and the Earth climate at geological timescales. The major results can be summarized as follow: (1) weathering of continental basaltic lithologies accounts for about 30% of the total consumption of atmospheric CO2 through weathering of continental silicate rocks. This is related to their high weatherability (about eight times greater than the granite weatherability); (2) a simple weathering law has been established for basaltic lithologies, giving the consumption of atmospheric CO2 as a function of regional continental runoff, and mean annual regional temperature; (3) no such simple weathering law can be proposed for granitic lithologies, since the effect of temperature can only be identified for regions displaying high continental runoff; (4) a general law relating mechanical erosion and chemical weathering has been validated on small and large catchments. The consequences of these major advances on the climatic evolution of the Earth are discussed. Particularly, the impacts of the onset of the Deccan trapps and the Himalayan orogeny on the global carbon cycle are reinvestigated. To cite this article: B. Dupré et al., C. R. Geoscience 335 (2003). 相似文献
8.
新生代构造抬升对地表化学风化和全球气候变化的影响 总被引:9,自引:0,他引:9
全球新生代构造抬升 ,特别是南亚喜马拉雅青藏高原和南美安底斯山脉和Altiplano高原在新生代的抬升对地表化学风化和全球气候变化产生了重要影响。它对地表化学风化的影响主要表现为引起造山带地区化学风化能力的提高 ;而它对全球气候变化的影响则主要表现在两个方面 ,一是直接的物理影响 ,即通过对大气和海洋循环的影响来对大气变化产生作用 ;一是通过对地表硅酸盐岩石的化学风化造成大气CO2 变化和全球温度的改变 ,从而对气候变化产生间接的生物化学效应。目前看来 ,新生代构造抬升造成的大气CO2 浓度减少是造成全球新生代气候变冷的重要原因。这已得到了近 10年来计算机大气环流模型 (GCMs)数值模拟和野外实验研究的支持 ,但在关于地表化学风化的主要控制因素 ,以及海洋Sr同位素是否可作为反映地表化学风化速率变化的替代性标志和气候变化反馈机制等方面 ,还需要作进一步研究。 相似文献
9.
Yanmei Wu Peter D. Clift Jiabiao Li Shaoru Yin Yinxia Fang 《International Geology Review》2020,62(7-8):970-987
ABSTRACT We calculated the sedimentary budget of the Northwest Sub-basin (NWSB), South China Sea for different geological times based on interpretations of four multichannel seismic profiles across the basin with constraints from International Ocean Discovery Program (IODP) Expeditions 367 and 368 drilling results. Sedimentation was generally dominated by regional tectonic events and climate change, but complicated by local tectonic events and geographic position, which resulted in a specific sedimentary budget in the NWSB compared with other marginal basins and the Southwest Sub-basin. The sedimentation rate was relatively low following the opening of the NWSB but increased gradually during the Middle Miocene, corresponding to the uplift of the Tibetan Plateau and the Asian monsoon. It reached its peak in the Late Miocene, corresponding to uplift of the Dongsha Island region that caused intensive bypass of eroded sediments from the Baiyun Sag into the abyssal basin, and reduced again during the Pliocene because of sediment storage on the wide northern continental shelf area compared to the abyssal basin during a period of high-stand sea level. Increase in sedimentation during the Pleistocene suggests that continental erosion and sediment transport to the abyssal basin were enhanced by an intensified Asian summer monsoon and glacial-interglacial climate fluctuations. Since the opening of the NWSB, the primary sediment provenance has been from southern China, with minor contributions from the Red River, Hainan Island, as well as local uplifts on the continental shelf. 相似文献
10.
临夏盆地晚新生代哺乳动物群演替与青藏高原隆升背景 总被引:16,自引:0,他引:16
临夏盆地的晚新生代沉积中富含哺乳动物化石,以晚渐新世巨犀动物群、中中新世铲齿象动物群、晚中新世三趾马动物群和早更新世真马动物群的化石最为丰富。晚新生代是青藏高原快速隆升的时期,临夏盆地的4个主要哺乳动物群在构造剧烈变化的背景下发生了显著的更替。通过对不同动物群所代表的生态特征的分析,恢复了临夏盆地晚新生代以来的气候环境演变过程:晚渐新世以温暖湿润的森林环境为主,间杂有一些开阔地带;中中新世的森林更加茂密,水体更加丰富;晚中新世演变为炎热半干旱的稀树草原环境,季节性变化加强;早更新世气候寒冷而干燥,并伴有显著的海拔升高。青藏高原在晚渐新世的隆升幅度还不足以阻挡大型哺乳动物在高原南北的交流,但到中中新世已成为明显的障碍,至晚中新世对动物迁徙的阻碍作用更加突出,而临夏盆地在早更新世已经达到相当大的高度,产生了一个高原或高山的动物群 相似文献
11.
在百万年时间尺度上,大气、海洋中的二氧化碳浓度(PCO2,二氧化碳分压)和长期变化主要受岩浆-变质脱碳作用和硅酸盐风化作用(消耗二氧化碳)控制。因此,地球表层主要构造活动带的构造-岩浆活动对长期碳循环具有重要的驱动作用。本文在总结已发表文献的基础上,系统评估了大陆弧,尤其是晚白垩世大陆弧的岩浆作用和剥蚀作用的碳通量,并以此为依据探讨了大陆弧演化对于全球长期碳循环的影响。大陆弧岩浆作用以周期性(几十万年至一百百万年)岩浆爆发(magmatic flare-ups)为特征。在一个周期内,大规模岩浆喷发会导致CO2排放量大幅度增加,促进温室效应。但同时,大规模的岩浆作用又会导致地壳增厚和和地表抬升,从而促进剥蚀作用、提高化学风化通量,进而增加CO2消耗量。对于单个的大陆弧来说,在其演化的不同阶段对于碳循环扮演着不同的角色:演化早期由于岩浆作用起主导作用,表现为净碳源;而在岩浆作用减弱或停止后,由于剥蚀作用的持续进行,表现为净碳汇。因此,从长周期和全球尺度上讲,大陆弧岩浆活动表现的“碳源属性”受到化学风化作... 相似文献
12.
The present Cenozoic era is an icehouse episode characterized by a low sea level. Since the beginning of the industrial revolution, the human race has been emitting greenhouse gases, increasing the global atmospheric temperature, and causing a rise in sea level. If emissions continue to increase at the present rate, average global temperatures may rise by 1.5°C by the year 2050, accompanied by a rise of about 30 cm in sea level. However, the prediction of future climatic conditions and sea level is hampered by the difficulty in modelling the interactions between the lithosphere, kryosphere, biosphere and atmosphere; in addition, the buffering capacity of our planet is still poorly understood. As scientists cannot offer unambiguous answers to simple questions, sorcerer's apprentices fill in the gaps, presenting plans to save planet without inconveniencing us.The geological record can help us to learn about the regulation mechanisms of our planet, many of which are connected with or expressed as sea level changes. Global changes in sea level are either tectono-eustatic or glacioeustatic. Plate tectonic processes strongly control sea levels and climate in the long term. There is a strong feed-back mechanism between sea level and climate; both can influence and determine each other. Although high sea levels are a powerful climatic buffer, falling sea levels accelerate climatic accentuation, the growth of the polar ice caps and will hence amplify the drop in sea level. Important sources of fossil greenhouse gases are botanic CO2 production, CO2 released by volcanic activity, and water vapour. The latter is particularly important when the surface area of the sea increases during a rise in sea level (maritime greenhouse effect). A volcanogenic greenhouse effect (release of volcanogenic CO2) is possibly not equally important, as intense volcanic activity may take place both during icehouse episodes as well as during greenhouse episodes. The hydrosphere, land vegetation and carbonate platforms are major CO2 buffers which may both take up and release CO2. CO2 can be released from the ocean due to changes in the pCO2 caused by growth of coral reefs and by uptake of CO2-rich freshwater from karst provinces. Efficient sinks of CO2 are the weathering products of silicate rocks; long-term sinks are organic deposits caused by regional anoxic events which preferrably develop during sea level rises and highstands; and coal-bearing strata. Deposition of limestone also removes CO2 from the atmospheric-hydrospheric cycle at a long term. Biotic crises are often related to either sea-level lows or sea-level highs. Long-term sea-level lows, characteristic of glacial periods, indicate cooling as major cause of extinction. During verly long-lasting greenhouse episodes the sea level is very high, climate and circulation systems are stable and biotic crises often develop as a consequence of oxygen depletion. On land, niche-splitting, complex food web structures and general overspecialization of biota will occur. Whether the crisis is caused by a single anoxic event (e.g. in the Late Devonian) or a disturbance by an asteroid impact (e.g. the Cretaceous/Tertiary boundary), it will only trigger total collapse of an ecosystem if a large part of it was already in decline. The regulatory mechanisms and buffers are thermodynamically extremely efficient if they are given sufficient time in which to deploy their power. However, after major catastrophes the re-establishment of successful ecosystems will take millions of years. The present rate of sea level and associated temperature rise is much too fast to be compensated and buffered by the network of natural controls. It is likely that the transitional time towards a new steady state will be an extremely variable and chaotic episode of unpredictable duration.
Correspondence to: H. Seyfried 相似文献
13.
任一特定时期的地质演化都必定源自前期背景,并影响后继地质作用。元古宙的构造特征及晚古生代的地质记录可帮助我们更好地认识早古生代华北板块的构造-沉积演化,这一演化包括4 个阶段。第1 阶段(∈1-∈3)以被动陆缘的发育和全球海平面上升为特点,二者叠加形成强烈的相对海平面上升,并在南、北边缘形成早期沉积。第2 阶段(O1y-O1l)表现为因洋壳俯冲导致的西南部构造抬升及全球海平面下降,二者结合形成的相对海平面下降在华北中部及西南部形成分布广泛的不整合面及白云岩。第3 阶段(O1m-O2)期间,来自南、北的挤压导致以边缘上凸为特点的板块变形,在伴以全球海平面上升的情况下导致轻度的相对海平面上升并形成板块中部局限陆表海的膏岩沉积。第4 阶段(O3-C1)则是强烈的南北挤压和全球海平面下降导致华北大陆板块整体鞍状抬升和长期不整合的发育,该不整合在北部及南部的侵蚀作用明显强于中部。 相似文献
14.
重大地史事件、节律及圈层耦合 总被引:4,自引:0,他引:4
文章讨论了岩石圈的联合古陆事件,生物圈的重要生物类别的出现、生物爆发事件和集群绝灭事件,水圈和大气圈的海平面变化事件和气候的变冷、变暖事件。联合古陆事件包括陆核型联合古陆(2500Ma)、初始原地台型联合古陆(1900Ma)、成熟原地台型联合古陆(1450Ma)、地台型联合古陆(850Ma)和大陆型联合古陆(250Ma)事件;生物圈事件包括原核生物、真核生物、后生动物、带壳后生动物的出现事件,寒武纪生物大爆发事件,奥陶纪—志留纪之交(439Ma)、晚泥盆世弗拉斯期—法门期之交(367Ma)、二叠纪—三叠纪之交(250Ma)、三叠纪—侏罗纪之交(208Ma)、白垩纪—第三纪之交(65Ma)的生物集群绝灭事件,并从遗迹化石的角度,阐述了后生动物及其行为习性的起源和演化的新观点。水圈和大气圈事件包括晚震旦世、奥陶纪—志留纪之交、晚石炭世的自节律海平面变化事件,奥陶纪和白垩纪的他节律高海平面事件,震旦纪—寒武纪和二叠纪—三叠纪之交的耦合节律海平面变化事件,并以泥盆纪为例作了进一步阐述。这些事件是岩石圈、生物圈、水圈和大气圈发展、演化的重要里程碑。上述事件的重要特征是,在时间上的节律性和在成因上的圈层耦合效应。 相似文献
15.
The integration of terrestrial carbonate δ13C chemostratigraphy and radiometric dates is opening a new window into the continental paleoclimate dynamics of the major carbon cycle perturbations of the Aptian-Albian interval. Results published to date by many researchers clearly show that there was a tight temporal coupling between Aptian-Albian marine, atmospheric, and terrestrial carbon pools that now permits refined global chemostratigraphic and chronostratigraphic correlations on time scales of 106 years or less. This development opens new opportunities to explore the Aptian-Albian Earth system by incorporating continental climate change dynamics in a developing global synthesis. In this paper, we present new U–Pb and U–Th/He age dates on a late Albian volcanic ash deposit in a stratigraphic section that fills a previous gap in in the terrestrial δ13C record. Here we also present, for the first time, coordinated δ13Ccarbonate, δ18Ocarbonate, and δ13Corganic data from stacked successions of paleosols in Aptian-Albian terrestrial strata of the Cedar Mountain Formation of Utah, USA. From the whole of this record, the late Aptian C10 C-isotope feature is especially noteworthy as an interval of major global change. Coordinated carbonate and organic carbon isotope data from this interval suggest that this positive carbon isotope excursion (CIE) was related to a buildup of atmospheric pCO2 to a peak level of about 1200 ppmV over a period of several million years duration, above earlier Aptian baseline levels of about 1000 ppmV. The C10 interval was immediately preceded and followed by drawdowns in pCO2 to levels of about 800 ppmV, and the entirety of the Aptian-Albian record from the Cedar Mountain Formation suggests a long-term fall of pCO2 levels from about 1000 down to 600 ppmV. We suggest that the late Aptian buildup likely is related to submarine volcanic activity in the Kerguelen Large Igneous Province in the southern Indian Ocean. Strata of the C-10 C-isotope feature are also associated with sedimentary evidence for an aridification event in the leeward rain shadow of the Sevier Mountains. On the basis of diagenetic studies of dolomitized calcretes in this C10 interval, we calculate that the precipitation-evaporation deficit intensified to the extent that 35–50% of the shallow groundwater system was lost to the atmosphere through evaporation. 相似文献
16.
《Chemie der Erde / Geochemistry》2017,77(4):625-631
The chemical composition of the clay fraction separated from the carbonate rock of the north-eastern Baltoscandian Basin was analysed and interpreted. Increased contents of Rb, Zr, Nb, Ti and their Al2O3-normalised ratios were detected at several stratigraphical levels in the geological sections of the Middle Ordovician–Upper Llandovery. In the weathering areas, Rb, Zr, Nb, Ti and Al are sensitive to moist conditions in the clay-forming process. In the sedimentary basin, the contents of these elements in clay are preserved and allow to infer past climates. Humid events occurred in the Dapingian, Sandbian, early Katian and Hirnantian (Ordovician) and in the Middle and Late Llandovery (Silurian). Juxtaposition with the sea-level curve shows correlation of five humid climate intervals with eustatic transgressions, suggesting global causes for these climatic changes. The warm and humid events, lasting one to two million years, occurred as climaxes between ice ages. An exceptional humid event within the Hirnantian glacial time occurs during mid-Hirnantian transgression, i.e. at a time of relative warming, as well. 相似文献
17.
18.
14C测年与示踪用于研究四万年来的全球变化 总被引:2,自引:1,他引:2
14C测年方法由于其假设前提经受过严格的检验,测年精确度极高,在全新世范围可达±50年。因此,在建立晚更新世以来的气候年表、各种地层年表、史前考古年表以及研究晚更新世以来的地壳运动、地貌及植被变化等方面起了重要作用。作为示踪剂14C与树木年轮相配合,揭示了近万年来地球磁场,太阳活动与全球气候变化的变化规律,以及它们间的相关关系。 相似文献
19.
徐强 刘宝珺 余光明 G. Einsele W. Frisch 刘光华 J. Wendt A. Wetzel L. Ratschbacher H. P. Luterbacher 《沉积与特提斯地质》1993,(1):58-65
喜马拉雅特提斯中、新生代属印度板块北部被动大陆边缘。对充填这个被动大陆边缘的沉积物用“反剥法”(backstrippiog)进行研究,恢复了从被动大陆边缘到前陆盆地的抓降史。对分离出的盆地构造沉降曲线与McKenzie模式图版进行对比相关性分析,判断认为被动大陆边缘成熟期主要为热耗散沉降,前陆盆地时逆冲推覆动力为主要影响因素。 相似文献
20.
天山山脉隶属中亚造山带,晚新生代时期印度板块向亚洲板块俯冲的构造效应同样影响到天山地区,使这一晚古生代形成的造山带重新复活。天山南北两侧的晚第三纪和第四纪时期的地层正是对印度板块-亚洲板块碰撞带的响应,发生构造变形,形成了一系列逆冲断层和褶皱,指示这一区域的地壳在晚新生代变短和加厚。文章对天山北缘晚中新世以来的沉积进行了详细的磁性地层学和沉积学研究,结果表明:在研究的独山子背斜地区,磨拉石沉积最早出现于约7百万年前,说明天山山脉自7百万年前开始有一次构造隆升,研究区内7.00~2.58Ma间的巨厚砾石沉积主要是构造抬升的结果。而早更新世的西域砾岩沉积在很大程度上与第四纪时期全球冰期的来临,特别是北半球开始发育大规模冰川作用有关,因此西域砾岩应当是在第四纪冰川作用(气候变冷)及新构造运动共同作用下的产物。 相似文献