排序方式: 共有54条查询结果,搜索用时 15 毫秒
11.
Mud volcanoes recently discovered on the offshore Calabrian Arc are investigated at two sites 60 km apart, in water depths of 1650--2300 m, using swath bathymetry, 2D&3D multichannel seismic and cores. The seabed and subsurface data provide information on their formation and functioning in relation to tectonic activity during the rapid Plio-Quaternary advance of the accretionary prism. Fore-arc extension and thrust-belt compression are seen to have involved two main phases of activity, separated by a regional unconformity recording a mid-Pliocene (3.5–3.0 Ma) tectonic reorganization. The two sites of mud volcanism lie in contrasting tectonic settings (inner fore-arc basin vs central fold-and-thrust belt) and record differing forms of seabed extrusive activity (twin mud cones and a caldera vs a broad mud pie). At both sites, subsurface data show that mud volcanism took place throughout the second tectonic phase, since the late Pliocene; differing forms of mud extrusion were accompanied by subsidence to form depressions beneath and within extrusive edifices up to 1.5 km thick. The basal subsidence depressions point to sources within the succession of thrusts underlying the inner to central Arc, consistent with microfossils within cored mud breccias from both sites that are derived from strata as old as Late Cretaceous. 相似文献
12.
为了理解地震的发生和地壳结构不均匀性的关系,利用南加州地震台网的固定台和临时台所记录的2863个兰德斯余震和区域地震,共计107401个P波和19624个S波高质量的到时数据,采用地震层析成像方法得到了兰德斯地震区P波和S波的精细的三维速度结构和泊松比分布.结果显示,地震的发生和分布与地壳结构的横向不均匀性有密切的关系.总体上看,兰德斯地震区余震成丛分布,并被低速块体截断,其中4级以上地震大多分布于P波高、低速异常过渡区域或偏向高速块体一侧,这可能是因为高速区多属地壳脆性介质,易于造成应力集中,导致地震;反之,低速度区则可能代表破碎程度较高、富含流体或温度较高区域,因而更倾向于产生无震变形.基于兰德斯地震区强震震源位置、地震区P波、S波速度异常与泊松比分布推断,兰德斯地震区可能有流体存在.地壳流体易使地壳岩石弱化,从而引发大地震. 相似文献
13.
<正>We synthesize significant recent results on the deep structure and origin of the active volcanoes in mainland China.Magmatism in the western Pacific arc and back-arc areas is caused by dehydration of the subducting slab and by corner flow in the mantle wedge,whereas the intraplate magmatism in China has different origins.The active volcanoes in Northeast China(such as the Changbai and Wuda-lianchi) are caused by hot upwelling in the big mantle wedge(BMW) above the stagnant slab in the mantle transition zone and deep slab dehydration as well.The Tengchong volcano in Southwest China is caused by a similar process in the BMW above the subducting Burma microplate(or Indian plate). The Hainan volcano in southernmost China is a hotspot fed by a lower-mantle plume which may be associated with the Pacific and Philippine Sea slabs' deep subduction in the east and the Indian slab's deep subduction in the west down to the lower mantle.The stagnant slab finally collapses down to the bottom of the mantle,which can trigger the upwelling of hot mantle materials from the lower mantle to the shallow mantle beneath the subducting slabs and may cause the slab—plume interactions. 相似文献
14.
The subduction of hydrated oceanic lithosphere potentially transports large volumes of water into the upper mantle; however,
despite its potential importance, fluid–rock interaction during high-pressure metamorphism is relatively poorly understood.
The stable isotope and major element geochemistry of Pennine ophiolite rocks from Italy and Switzerland that were metamorphosed
at high pressures are similar to that of unmetamorphosed ophiolites, suggesting that they interacted with little pervasive
fluid during high-pressure metamorphism. Cover sediments also have oxygen isotope ratios within the expected range of their
protoliths. In the rocks that escaped late greenschist-facies retrogression, different styles of sub-ocean-floor alteration
may be identified using oxygen isotopes, petrology, and major or trace element geochemistry. Within the basalts, zones that
have undergone high- and low-temperature sub-ocean-floor alteration as well as relatively unaltered rocks can be distinguished.
Serpentinites have δ18O and δ2H values that suggest that they were formed by hydration on or below the ocean floor. The development of high-pressure metamorphic
mineralogies in metagabbros occurred preferentially in zones that underwent sub-ocean-floor alteration and which contained
hydrated, fine-grained, reactive assemblages. Given that the transformation of blueschist-facies metabasic rocks to eclogite-facies
assemblages involves the breakdown of hydrous minerals (e.g. lawsonite, zoisite, and glaucophane), and will thus liberate
considerable volumes of fluids, metamorphic fluid flow must have been strongly channelled. High-pressure (quartz+calcite±omphacite±glaucophane±titanoclinohumite)
veins that cut the ophiolite rocks represent one possible channel; however, stable isotope and major element data suggest
that they were not formed from large volumes of exotic fluids. Fluids were more likely channelled along faults and shear zones
that were active during high-pressure metamorphism. Such strong fluid channelling may cause fluids to migrate toward the accretionary
wedge, especially along the slab–mantle interface, which is probably a major shear zone. This may preclude all but a small
fraction of the fluids entering the mantle wedge to flux melting. Additionally, because fluids probably interact with relatively
small volumes of rock in the channels, they cannot "scavenge" elements from the subducting slab efficiently.
Received: 28 January 1999 / Accepted: 2 February 1999 相似文献
15.
Mechanical properties of high porosity chalks are strongly dependent on the type of fluid in the pores. Dry chalk is considerably stronger than water-saturated chalk, and this phenomenon is often referred to as the water-weakening effect. To address the problem of chalk–fluid interactions, several series of tests have been performed with glycol and high concentration brines as saturating fluids. Glycol is a fluid that in many aspects resembles oil, except that glycol is miscible with water. Glycol-saturated chalk turns out to have properties very similar to oil-saturated chalk. Compared to dry chalk, both oil and glycol make the chalk somewhat weaker, but this weakening effect is much less than with water. Several series of tests with brines with high concentrations of calcium chloride or sodium chloride show that the water-weakening effect is considerably reduced in high ionic strength solutions. Most tests were performed as quasi-hydrostatic tests, with a constant stress ratio of 0.9. In such tests, the yield point marks the onset of accelerated pore collapse, and the yield value is close to the hydrostatic yield stress. In addition to these compressive tests, a series of Brazilian tests were performed, revealing the same trend. The variations in mechanical strength have been correlated with the activity of water in the brines. Within the experimental accuracy of the compressive tests, there is a linear trend between reduction of water activity and the corresponding increase in strength. This leads to the hypothesis that the water activity may be a key parameter in the water-weakening mechanism. But this conclusion also indicates that water weakening may be a special case of general chalk–fluid interactions where the degree of weakening depends on the strength of adsorption of the fluid molecules to the calcite surfaces. 相似文献
16.
A.M. Gabrielov V.I. Keilis-Borok V. Pinsky O.M. Podvigina A. Shapira V.A. Zheligovsky 《Tectonophysics》2007,429(3-4):229-251
We explore the impact of fluids migrating through a fault network on the dynamics of lithosphere, both on slow movements and seismicity. For that purpose fluids in the fault zones are incorporated into modelling of blocks-and-faults systems, which takes into account driving forces and the system's geometry. Simulations have been performed for two-dimensional models: an idealised “brick wall” structure, and a coarse image of Sinai Subplate. Migrating fluids originating in different locations are considered, as well as fluids trapped in closed pockets. Basic features of the modelled and observed seismicity are in good accord, as shown by comparison with the earthquake catalog compiled by Geophysical Institute of Israel. 相似文献
17.
The role of fluids in faulting deformation:a case study from the Dead Sea Transform (Jordan) 总被引:1,自引:1,他引:0
C. Janssen R. L. Romer A. Hoffmann-Rothe B. Mingram P. Dulski P. Möller H. Al-Zubi 《International Journal of Earth Sciences》2005,94(2):243-255
The geochemistry of carbonate fault rocks has been examined in two areas of the Arava Fault segment, which forms the major branch of the Dead Sea Transform between the Dead Sea and the Gulf of Aquaba. The role of fluids in faulting deformation in the selected fault segment is remarkably different from observations at other major fault zones. Our data suggest reduced fluid rock interactions in both areas and limited fluid flow. The fault did not act as an important fluid conduit. There are no indications that hydrothermal reactions (cementation, dissolution) did change the strength and behavior of the fault zone, although the two areas show considerable differences with respect to fluid sources and fluid flow. In one area, the investigated calcite mineralization reveals an open fluid system with fluids originating from a variety of sources. Stable isotopes (13C, 18O), strontium isotopes, and trace elements indicate both infiltration of descending (meteoric and/or sea water) and ascending hydrothermal fluids. In the other area, all geochemical data indicate only local (small scale) fluid redistribution. These fluids were derived from the adjacent limestones under nearly closed-system conditions. 相似文献
18.
To trace the fluid history of sedimentary basins requires integration of relatively diverse sub-disciplines including sedimentology, stratigraphy, tectonics, structural geology, petrography, geochemistry and geophysics. These aspects of basin evolution are interrelated and thus all are required to understand the source, character and distribution of fluids associated with ore deposits hosted in basins. Fluids are strategically associated with both the formation and preservation of almost every type of economic ore deposit in basins. As such, knowledge of the geochemical and physical characteristics, timing, origin, reactivity and flow histories of fluids are basic to formulating effective exploration strategies. 相似文献
19.
20.
《地学前缘(英文版)》2020,11(3):989-998
Regions of slow strain often produce swarm-like sequences, characterized by the lack of a clear mainshock-aftershock pattern. The comprehension of their underlying physical mechanisms is challenging and still debated. We used seismic recordings from the last Pollino swarm (2010–2014) and nearby to separate and map seismic scattering (from P peak-delays) and absorption (from late-time coda-wave attenuation) at different frequencies in the Pollino range and surroundings. High-scattering and high-absorption anomalies are markers of a fluid-filled fracture volume extending from SE to NW (1.5–6 Hz) across the range. With increasing frequency, these anomalies approximately cover the area where the strongest earthquakes occurred from the sixteenth century until 1998. In our interpretation, the NW fracture propagation ends where carbonates of the Lucanian Apennines begin, as marked by a high-scattering and low-absorption area. At the highest frequency (12 Hz) the anomalies widen southward in the middle of the range, consistently marking the faults active during the recent Pollino swarm. Our results suggest that fracture healing has closed small-scale fractures across the SE faults that were active in the past centuries, and that the propagation of fluids may have played a crucial role in triggering the 2010–2014 Pollino swarm. Assuming that the fluid propagation ended at the carbonates barrier in the NW direction, fractures opened new paths to the South, favoring the nucleation of the last Pollino swarm. Indeed, the recently active faults in the middle of the seismogenic volume are marked by a high-scattering and high-absorption footprints. Our work provides evidence that attenuation parameters may track shape and dynamics of fluid-filled fracture networks in fault areas. 相似文献