Abstract Variation in the state of stress during heterogeneous deformation should be reflected in variation in the effective pressure of metamorphic reactions, whether this is mean stress or the normal stress acting across the reacting interface. The magnitude of this pressure variation will determine whether it is discernible in the preserved metamorphic mineral assemblages of heterogeneously deformed rocks. The magnitude of the mean stress difference across a non-slipping interface between two materials with viscosity ratio >c. 20:1 is effectively equal to the maximum shear stress for flow in the more viscous material. Progressive shortening of the interface results in a higher mean stress in the more competent material, whereas extension results in a lower mean stress. For high-P/low-T eclogite facies conditions, current experimental data indicate that clinopyroxene- and garnet-rich layers of eclogite should be very strong and that pressure differences of up to 800 MPa (8 kbar) between competent layer and weaker matrix may be possible. Such high values can be obtained in widely separated competent layers for values of bulk stress in the overall multilayer that are much lower (by a factor approaching the viscosity ratio). Extrusion of material between more rigid plates, which has been proposed as a regional mechanism of lateral ‘continental escape’for both the Alps and the Himalayas, should also be accompanied by a lateral gradient in effective pressure; otherwise extrusion could not occur. Maximum mean stresses with magnitudes that are many times the maximum shear stress required for plastic flow should develop for deformation zones that are long relative to their width (e.g. around 20 times for a width-to-thickness ratio of 10). Tectonic overpressure in progressively shortened competent layers, particularly in regions of extrusion between more rigid plates, might help explain the occurrence of isolated layers and pods of low-T eclogite (<550°C) with estimated peak pressures markedly in excess of those in the surrounding matrix. It cannot explain the occurrence of isolated high-T eclogites, because at temperatures >c. 550°C, the dramatic weakening of clinopyroxene in the power-law creep field precludes the development of significant overpressures in eclogite layers. 相似文献
Abstract The Catalina Schist of southern California is a subduction zone metamorphic terrane. It consists of three tectonic units of amphibolite-, high- P greenschist- and blueschist-facies rocks that are structurally juxtaposed across faults, forming an apparent inverted metamorphic gradient. Migmatitic and non-migmatitic metabasite blocks surrounded by a meta-ultramafic matrix comprise the upper part of the Catalina amphibolite unit. Fluid-rock interaction at high- P , high- T conditions caused partial melting of migmatitic blocks, metasomatic exchange between metabasite blocks and ultramafic rocks, infiltration of silica into ultramafic rocks, and loss of an albitic component from nonmigmatitic, clinopyroxene-bearing metabasite blocks. Partial melting took place at an estimated P =˜8–11 kbar and T =˜640–750°C at high H2O activity. The melting reaction probably involved plagioclase + quartz. Trondhjemitic melts were produced and are preserved as leucocratic regions in migmatitic blocks and as pegmatitic dikes that cut ultramafic rocks. The metasomatic and melting processes reflected in these rocks could be analogous to those proposed for fluid and melt transfer of components from a subducting slab to the mantle wedge. Aqueous fluids rather than melts seem to have accomplished the bulk of mass transfer within the mafic and ultramafic complex. 相似文献
1. INTROOrCTIOXThe upper Tisza in Hungary is a sand bed alluvial river. presenting several river training problems. In order to solve these problems first the laws of free river--bed evolution must be clarified thenthe effects of existing river training s… 相似文献
The Graveyard Point intrusion is the only known example of awell-exposed differentiated mafic pluton associated with thelate MiocenePleistocene magmatism of the western SnakeRiver Plain (SRP). It is exposed in a 6 km by 4 km area adjacentto the OregonIdaho border, and exposures range in thicknessfrom 20 to 160 m. The thicker parts of the intrusion are stronglydifferentiated and contain a 2560 m thick section ofwell-laminated cumulus-textured gabbros that grade upward intopegmatoidal ferrogabbro. Evolved liquids formed sheets of Fe-richsiliceous granophyre. At least two injections of magma are indicatedby abrupt discontinuities in the rock and mineral compositions,and by the lack of mass balance between the bulk intrusion andits chilled borders. The laminated gabbros are interpreted tohave formed from a tongue of augite and plagioclase crystalsthat were carried in with the second pulse of magma. Followingthe final emplacement of the intrusion, in situ differentiationproceeded through a two-stage process: the ferrogabbros areexplained as interstitial liquids forced out of the crystalmush by compaction, and the siliceous granophyres are interpretedto be residual liquids that migrated out of the partly crystallizedferrogabbros in response to the exsolution of volatiles. Becausethe geochemical trend inferred for the mafic to intermediatecomposition liquids in the Graveyard Point intrusion is similarto the trend for many western Snake River Plain lavas, the plutonmay be a good model for shallow sub-volcanic magma chamberselsewhere in the SRP. However, some western SRP lavas containanomalously high concentrations of P2O5 , which are best explainedby mixing within the active crustal mush column or with partialmelts of previously formed differentiated mafic intrusions. KEY WORDS: Snake River Plain; mafic intrusions; tholeiitic; sill; granophyre相似文献
Clastic dikes are formed either by passive deposition of clastic material into pre-existing fissures (depositional dikes), or by fracturing and injection of clastics during earthquakes (injection dikes). We proposed to use optically stimulated luminescence (OSL) dating to distinguish between the two modes of formation and hypothesized that (1) depositional dikes filled from above show OSL ages younger than the host rock; and (2) injection dikes filled from below show the same OSL ages as that of the host rock. We studied the mechanisms of clastic-dike formation and their ages within the seismically active Dead Sea basin, where hundreds of dikes crosscut the late Pleistocene (70–15 ka) lacustrine sediments of the Lisan Formation. Field observations and analysis of magnetic tensors show unequivocally that most of these dikes were emplaced by injection, inferred to be due to seismically triggered fluidization–liquefaction during earthquakes. Twenty-eight samples were collected from the Lisan source material and dikes that, based on field observations, are unmistakably either depositional dikes or injection dikes.
Quartz single aliquot OSL ages of the source Lisan layers are between 43 and 34 ka, and are typical for the Lisan Formation. The ages of both depositional and injection dikes are between 15 and 17 ka, younger than the Lisan host rock. Depositional dikes show a highly scattered distribution of single grain ages, suggesting several episodes of infill. Single grain ages of injection dikes are of latest Pleistocene to Holocene, and do not contain recently bleached grains that infiltrated from above. These results imply that the OSL signals were reset at the time of fluidization–liquefaction and buildup of fluid pressure within the injection dikes. If this resetting mechanism has a physical ground, then OSL dating is an important tool for constraining the ages of earthquake-induced injection dikes and recovering paleoseismic data from them. 相似文献