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1.
An experimental study of the system Zr-Fe-Ti-O in equilibrium with metallic iron has been conducted at atmospheric pressure and in the temperature range 950–1300° C, with the purpose of modelling sub-solidus relations between Zr-bearing Fe-Ti oxide phases in lunar rocks. The phase relations are governed by the coexistence of the Fe-Ti oxides with ZrO2 at temperatures below 1247° C, but with the new cubic ZFT phase at higher temperatures. ZFT, approximately Zr Fe Ti O5, is probably related to the so-called stabilized cubic zirconia and could represent a synthetic equivalent of some lunar Zr-Fe-Ti rich oxide minerals.The zirconium contents in all Fe-, Ti and Fe-Ti-oxide phases increase with increasing temperature. At each temperature, Zr is incorporated preferentially in the Ti-oxide (up to 11 wt% ZrO2), followed by ferropseudobrookite (up to 6 wt% ZrO2), ilmenite (max. 4 wt%) and wüstite (max. 2.5 wt%). Ulvöspinel coexisting with ilmenite (+Fe0+ ZrO2 and/or ZFT) always contains less than 1.2 wt% ZrO2, whereas the same mineral in assemblage with wüstite-ZrO2-Fe0 displays even higher ZrO2 contents than ilmenite (above 4 wt%). Considering that the values determined here in the synthetic parageneses represent saturation concentrations at high temperatures in a simple model system, the ZrO2 concentrations in the corresponding lunar minerals should generally be significantly lower. This is realized, except for the so-called Cr-Zr-Ca armalcolites which display ZrO2 contents in the range 3.5–7 wt% and are thus probably related rather to Zr-rich oxide minerals than to armalcolite itself.  相似文献   

2.
The exhaustive review of a long number of historical documents, books, reports,scientific and press reports, instrumental recordings, previous catalogues andpersonal field observations, concluded with the production of a completely newtsunami catalogue for the Corinth Gulf, Central Greece, which is arranged in theformat adopted by the GITEC group for the new European Tsunami Catalogue.The catalogue is presented in three sections: the Quick-Look Table, the Quick-LookAccounts File and the References File. An Appendix explains why some particularsea disturbances were not included in the new catalogue although they were consideredas tsunami events by previous researchers. Past history clearly shows that most tsunamis in the Corinth Gulf are produced by strong (Ms 5.5) offshore and near shore earthquakes. However, seismic or aseismic sliding of coastal and submarine sediments is a significant factor in tsunamigenesis. Calculations based on the random model indicate that the probability for at least one tsunami occurrence of intensity TI 2 TI 3 and TI 4 within 50 years equals 0.851, 0.747 and 0.606, respectively. From the intensity–frequency relationship the mean return period of tsunami intensity TI 2, TI 3 and TI 4 equals to 16, 40 and 103 years. The tsunami geographicaldistribution, however, is non-random with a clear trend for the tsunamigenesis todecrease drastically from west to east within the Corinth Gulf. In fact, the probabilityfor a strong earthquake to cause a tsunami of TI 3 in the Corinth Gulf consideredas an entity is 0.35, while in the western part of the Gulf it goes up to 0.55. Therefore, the rapid and accurate determination of the earthquake focal parameters is of great importance in an algorithm of a real-time tsunami warning system in the Corinth Gulf.  相似文献   

3.
Monomineralic domains of chlorite, corundum and Cr muscovite coexist over a kilometer scale within ultramafic schists of the Harare greenstone belt (2.73 Ga). This exotic lithological association includes the conjunction of some of the most aluminous (Al2O388 wt%) and potassic (K2O10 wt%) rocks known. The paragenetic sequence developed from chloritecorundumcorundum+ diaspore: Cr muscovite variably overprinted both the corundum and chloritite domains. Terminal stages were marked by sporadic production of andalusite+quartz, and finally margarite.Chlorite (Cr2O3=0.31–2.65 wt%), corundum (0.79–2.66 wt%), and diaspore are all Cr-rich varieties. The chromian (Cr2O33.86 wt%) paragonitic muscovite incorporates up to 17% of the paragonite molecule, and significant Mg and Fe substitutions.The suite of rocks are characterized by chondritic Ti/Zr ratios (–x=107), systematically enhanced Cr (up to 14000 ppm) and Ni (up to 1200 ppm) abundances, low levels of the alteration-insensitive incompatible elements Th, Ta, Nb. Chlorite, corundum and Cr muscovite represent progressive stages in the incremental metasomatic alteration of a komatiite precursor. Mass balance calculations, constrained by the isochemical behaviour of Ti, Zr and Hf reveal that the komatiite chloritite transformation involved volumetric contractions of 60% by hydrothermal leaching of Si, Fe, Mn, Ca and Na. Reaction of chloritite to corundum involved further volumetric reductions of 50% due to essentially quantitative loss of Si, Fe, Mn, Mg, K and Ca. Conversion of corundum to muscovite required additions of Si, K, Fe, Mn, Mg, Rb and Ba at 50–200% dilation. K, Rb, Ba, Li and Cs are enriched by up to 2×103 over background abundances in ultramafic rocks, and the suite is also enriched in B, Se, Te, Bi, As, Sb and Au. REE were extensively leached during chloritite-corundum stages, whereas LREE additions accompany development of muscovite. Ti, Zr, Hf and Al were all concentrated by selective leaching of mobile components, but absolute additions of Al accompanied development of the corundum domains due to Al precipitation in response to depressurization.Corundum ( 18O=3.5–4.8), muscovite ( 18O=6.7–7.5) and chlorite (4.5–5.6) are isotopically uniform and formed at 380–520° C from a fluid where 18O=5.6–6.9. The corundum is 18O depleted relative to either igneous or anatectic counterparts (Ocor=7.6–8.2), or to gibbsitic laterites ( 18O=12–17).Previous genetic schemes involving metamorphism of exhalites or bauxite, or Si-undersaturation of magmas, can all be ruled out from the data. The chloritite, corundum, Cr-muscovite association represents sequential alteration products of ultramafic rocks by high temperature, low pH hydrothermal solutions carrying LIL-elements, and in which excursions of pH and/or degree of quartz undersaturation account for the mineralogical transitions. A deep level acid epithermal system, or fluid advection across steep inverted thermal gradients in a thrust regime could account for required hydrothermal conditions.  相似文献   

4.
Integrated petrologic and Sm–Nd isotopic studies in garnet amphibolites along the Salmon River suture zone, western Idaho, delineate two periods of amphibolite grade metamorphism separated by at least 16 million years. In one amphibolite,P–T studies indicate a single stage of metamorphism with final equilibration at 600°C and 8–9 kbar. The Sm–Nd isotopic compositions of plagioclase, apatite, hornblende, and garnet define a precise, 8-point isochron of 128±3 Ma (MSWD=1.2) interpreted as mineral growth at the metamorphic peak. A40Ar/39Ar age for this hornblende indicates cooling through 525°C at 119±2 Ma. In a nearby amphibolite, garnets with a two-stage growth history consist of inclusion-rich cores surrounded by discontinuous, inclusion-free overgrowths. Temporal constraints for core and overgrowth development were derived from Sm–Nd garnet — whole rock pairs in which the garnet fractions consist of varying proportions of inclusion-free to inclusion-bearing fragments. Three garnet fractions with apparent ages of 144, 141, and 136 Ma are thought to represent mixtures between late Jurassic (pre-144 Ma) inherited radiogenic components preserved within garnet cores and early Cretaceous (128 Ma) garnet overgrowths. These observations confirm the resilience of garnet to diffusive exchange of trace elements during polymetamorphism at amphibolite facies conditions. Our geochronologic results show that metamorphism of arc-derived rocks in western Idaho was episodic and significantly older than in arc rocks along the eastern margin of the Wrangellian Superterrane in British Columbia and Alaska. The pre-144 Ma event may be an expression of the late Jurassic amalgamation of marginal oceanic arc-related terranes (e.g., Olds Ferry, Baker, Wallowa) during the initial phases of their collision with North American rocks. Peak metamorphism at 128 Ma reflects tectonic burial along the leading edge of the Wallowa arc terrane during its final penetration and suturing to cratonic North America.  相似文献   

5.
Soil samples collected from various places in and around Mysore were analyzed for the total trace elements such as Fe, Mn, Cu, Zn, Pb, and Cd. The results of the analysis indicate that the concentration of lead and cadmium in soils is below 2.5 g ml–1 and 0.2 g ml–1, respectively, which are the minimum detection levels, whereas the concentration of iron, manganese, copper, and zinc in most of the samples is within the global average ranges of 3%, 500–1000 g g–1, 15–40 g g–1, and 50–100 g g–1, respectively. The investigated area has the presence of gneisses and schists, in which partly there are igneous intrusions and pegmatitic intrusions. There are amphibolite enclaves in gneisses that account for the higher concentration of trace elements. The lower concentration may be attributed to the presence of silicic type of rock.  相似文献   

6.
Summary The Ni–Cu–Platinum Group Element (PGE) sulfide deposits of the Sudbury Structure have provided a major portion of the worlds total nickel production and their host rocks have been the subject of numerous research studies, yet a number of perplexing problems remain to be solved. On the one hand, studies seeking to explain the formation of the Sudbury Structure have now converged on a genetic model which proposes that the Main Mass and Offset Dykes of the Sudbury Igneous Complex (SIC) were produced by crystallization of an impact-generated melt sheet. On the other hand, these models have yet to be fully reconciled with the production of the very large volume of magmatic Ni, Cu, Co, and PGE-rich sulfide mineralization and the associated mafic rock types. This paper explores this problem using new precious metal data from the Main Mass and Offset Dykes. These data are used to understand the relationships between these rocks, and to provide constraints on how the Ni–Cu–PGE sulfide ore deposits fit into the geological evolution of the Sudbury Structure.In the two drill cores selected for study in this project, the Mafic Norite has 1–5 modal percent pyrrhotite plus chalcopyrite, and elevated Ni (40–1000ppm), Cu (40–1140ppm), and PGE (1.9–7.8ppb Pd, 1.8–7.3ppb Pt); this is overlain by Felsic Norite that contains pyrrhotite, and has a wide range in concentration of Ni (13–257ppm), Cu (7–328ppm), and PGE (<0.01–6.4ppb Pd, <0.01–5ppb Pt). For a similar range of MgO, the upper portion of the Felsic Norite unit has 5–10 times lower Ni and Cu abundances than within-plate basalts and local crustal rocks, and PGE abundance levels are mostly below analytical determination limits. Stratigraphic studies of other compositional profiles around the SIC demonstrate that this depletion signature of Ni, Cu, and PGE is widespread and developed not only above mineralized embayments and offsets, but also above barren sections of the lower contact of the SIC.The depletion of the upper part of the Felsic Norite in Ni, Cu and PGE is presumably due to equilibration of the magma with magmatic sulfide, and accumulation of this dense sulfide liquid. Results of modeling indicate that the parental magma giving rise to the Mafic and Felsic Norites had initial Ni and Cu contents of 210 and 110ppm, respectively. In addition, Ni, Cu and PGE tenors calculated in 100% sulfide from the Copper Cliff Offset average 13% Cu, 6% Ni, 18ppm Pd, and 19ppm Pt indicating that these sulfides had formed by fractionation from magmas that contained 310ppm Ni, 310ppm Cu, 18ppb Pd and 19ppb Pt. These values are factors of 3 to 5 higher than the Ni, Cu, Pd, and Pt contents of the Onaping Formation with average values of 55ppm Ni, 48ppm Cu, and 4.9ppb Pd as well as the marginal sulfide-poor phase of the Worthington Offset quartz diorite, which has average values of 61ppm Ni, 59ppm Cu, 2.8ppb Pd and 4.0ppb Pt. Both the Onaping Formation and the marginal quartz diorite are believed to represent the initial composition of a large component of the melt sheet. There is therefore a fundamental problem in reconciling the initial metal contents of the SIC magma as indicated by the marginal phases of the Offset dykes and that of the Onaping Formation with the composition of the SIC magma at the times of formation of the sulfides as indicated by their Ni, Cu and PGE tenors.It is proposed that because the SIC melt sheet was initially superheated with a temperature of 1700°C, it was able to dissolve 5 times as much S as it could at its liquidus temperature of 1200°C. It was also initially composed of an emulsion of mafic and felsic melts (Marsh and Zieg, 1999), which may have formed discrete magma cells. As the temperature of the melt sheet decreased, some of these magma cells became S-saturated and the resultant Ni–Cu–PGE sulfides settled downwards and on reaching magma cells lower in the melt sheet were re-dissolved thereby raising the Ni, Cu and PGE contents of the lower magma cells. It was from these enriched magma cells that precipitation of the ore-forming Ni–Cu–PGE sulfide melts eventually took place.The mineral potential of Offset and embayment structures appears to be empirically linked to the thickness of the overlying noritic rocks; for example, the most heavily mineralized embayments and Offset Dykes are located in areas where the Felsic Norite is thickest. It appears unlikely that the entire 1–3km-thick melt sheet was convectively mixing throughout its lateral extent, and so the heterogeneity in sulfide distribution was retained after crystallization and cooling.  相似文献   

7.
The Xihuashan stock (South Jiangxi, China) is composed of cogenetic granitic units (granites Xe, a, c, d and b) and emplaced during the Yanshanian orogeny (153±0.2 Ma). They are two feldspars, Fe-rich biotite±garnet and slightly peraluminous granites. Primary accessory minerals are apatite 1, monazite, zircon, uranothorite±xenotime in granites Xe and a, zircon, uranothorite, uraninite, betafite, xenotime 1; hydrothermal minerals are monazite altered into parisite and apatite 2, Y-rich parisite, yttroparisite, Y-rich fluorite and xenotime 2 in granites c and b. Petrographic observations, major element, REE, Y and Rb–Sr isotropic data point to a magmatic suite (granites Xe and a granites c and d granite b) distinct from hydrothermal Na-or K-alteration of b. From granite Xe to granite b, LREE, Eu, Th and Zr content are strongly depleted, while HREE, Y and U content increase. During K-alteration of b, these variations are of minor importance. Major and accessory mineral evidences, geochemical and fluid inclusion results indicate two successive alteration fluids interacting with b, (1) a late-magmatic F and CO2–rich fluid and (2) a post-magmatic, aqueous and slightly saline fluid. The depletion of LREE and Th content and the increase in HREE, Y and U content correspond, in the magmatic suite to the early fractionation of monazite in the granites where there is no hydrothermal alteration (granites Xe and e) and to the hydrothermal alteration of monazite into parisite and secondary apatite, intense new formation of yttroparisite, Y enrichment and U loss in the uranothorite and late crystallization of uraninite in the granites c and b. Moreover, simulated crystallization of monazite and temperature of monazite saturation show early fractionation of monazite from the magma in the less evolved granites (Xe and e) and prevailing hydrothermal leaching of monazite in the most evolved granites (c-d and b) related to a late-magmetic event. The slight variations of REE, Y, Th and U content in the K-altered granites compared to granite b emphazes the distinct chemical nature of the successive hydrothermal fluids. Rb–Sr and Sm–Nd isotopic results point to a 30 Ma period of time between the late-magmatic and the post-magmatic fluid circulation.  相似文献   

8.
The Brixen Quartzphyllite, basement of the Southern Alps (Italy), consists of metasediments which had suffered progressive deformation and low grade metamorphism (p max4 kbar, T max375±25° C) during the Palaeozoic. It has been excavated by pre-Permian erosion, buried again beneath a pile of Permo-mesozoic to Cainozoic sediments (estimated T max150° C), and is now exposed anew due to late Alpine uplift and erosion. The behavior of the K-Ar system of white micas is investigated, taking advantage of the narrow constraints on their thermal history imposed by the geological/stratigraphic reference systems.The six structurally and petrographically differing samples come from a single outcrop, whose position is roughly two kilometers beneath the Permian land-surface. White mica concentrates from five grain size fractions (<2 , 2–6 , 6–20 , 20–60 , 60–75 ) of each sample have been analyzed by the conventional K-Ar method, four selected concentrates additionally by the 40Ar/39Ar stepwise heating technique; furthermore, Ar content and isotopic composition of vein quartz were determined.The conventional ages of the natural grain size fractions (20–60 , 60–75) are in the range 316±8 Ma, which corresponds to the 40Ar/39Ar plateau age of 319.0±5.5 Ma within the error limits. The finer grain size fractions yield significantly lower ages, down to 233 Ma for fractions <2 . Likewise low apparent ages (down to 83 Ma) are obtained for the low temperature 40Ar/39Ar degassing steps.There is no correlation between microstructural generation of white mica prevailing in the sample and apparent age. This favours an interpretation of the 316±8 Ma values as cooling age; progressive deformation and metamorphism must be respectively older and their timing cannot be resolved by these methods. The data preclude any significant influence of a detrital mica component as well as of excess argon.The lower ages found for the fine grain-size fractions (respectively the low-T degassing steps) correspond to a near-surface period (p-T-minimum); the values are geologically meaningless. The effect is interpreted to result from partial Ar loss due to reheating during Mesozoic-Cainozoic reburial. A model based on diffusion parameters derived from the outgassing experiments and Dodson's (1979) equation yields a closure temperature of 284±40 °C for a cooling rate of 18° C/Ma. Furthermore, this model suggests that the observed argon loss of up to 5% may in fact have been induced by reheating to 150 °C for 50 Ma.  相似文献   

9.
The Mount Lofty Ranges comprises interlayered marbles, metapsammites, and metapelites that underwent regional metamorphism during the Delamarian Orogeny at 470–515 Ma. Peak metamorphic conditions increased from lowermost biotite grade (350–400°C) to migmatite grade (700°C) over 50–55 km parallel to the lithological strike of the rocks. With increasing metamorphic grade, 18O values of normal metapelites decrease from 14–16 to as low as 9.0, while 18O values of calcite in normal marbles decrease from 22–24 to as low as 13.2 These isotopic changes are far greater than can be accounted for by devolatilisation, implying widespread fluid-rock interaction. Contact metamorphism appears not to have affected the terrain, suggesting that fluid flow occurred during regional metamorphism. Down-temperature fluid flow from synmetamorphic granite plutons (18O=8.4–8.6) that occur at the highest metamorphic grades is unlikely to explain the resetting of oxygen isotopes because: (a) there is a paucity of skarns at granite-metasediment contacts; (b) the marbles generally do not contain low-XCO2 mineral assemblages; (c) there is insufficient granite to provide the required volumes of water; (d) the marbles and metapelites retain a several permil difference in 18O values, even at high metamorphic grades. The oxygen isotope resetting may be accounted for by along-strike up-temperature fluid flow during regional metamorphism with time-integrated fluid fluxes of up to 5x109 moles/m2 (105 m3/m2). If fluid flow occurred over 105–106 years, estimated intrinsic permeabilities are 10-20 to 10-16m2. Variations in 18O at individual outcrops suggest that time-integrated fluid fluxes and intrinsic permeabilities may locally have varied by at least an order of magnitude. A general increase in XCO2 values of marble assemblages with metamorphic grade is also consistent with the up-temperature fluid-flow model. Fluids in the metapelites may have been derived from these rocks by devolatilisation at low metamorphic grades; however, fluids in the marbles were probably derived in part from the surrounding siliceous rocks. The marble-metapelite boundaries preserve steep gradients in both 18O and XCO2 values, suggesting that across-strike fluid fluxes were much lower than those parallel to strike. Up-temperature fluid flow may also have formed orthoamphibole rocks and caused melting of the metapelites at high grades.This paper is a contribution to IGCP Project 304 Lower Crustal Processes  相似文献   

10.
Present status of geologic mapping indicates that there are three major units of Precambrian rocks in Mexico. The oldest (older than 1,700 m. y.) and the youngest (younger than 700 m. y.) are confined to the northwest part of the country. The intermediate unit (1,300-800 m. y.) is distributed in eastern and southern Mexico and extend into northern Guatemala.The rocks making up the oldest unit accumulated as greywackees and associated volcanics in a eugeosyncline prior to 1,700 m. y. ago; this eugeosyncline extended into Mexico from the north-northeast, where it bordered the older Precambrian craton. These rocks underwent metamorphism and anatexis around 1,700 m. y. ago, that produced the development of the amphibolite-granulite facies and the emplacement of granitic stocks and batholiths.A similar history, but somewhat younger, is recorded for the Precambrian rocks in eastern and southern Mexico. These rocks accumulated in the southern continuation of the Grenville Geosyncline as greywackees and volcanics, starting about 1,300 m. y. ago. These rocks underwent metamorphism and anatexis during the interval of 1,000-900 m. y. ago to form the Oaxacan Structural Belt.An event of granitic magmatism, around 700 m. y. ago, is evidenced in the extreme northwest and southeast of Mexico which, heretofore is not recognized in Texas. In the northwest, this was followed by the intrusion of diabase dykes, prior to the deposition of the youngest Precambrian sediments.During latest Precambrian time, in northwest Mexico, an about 2,000 m thick sequence of conglomerate, sandy shale and dolomite, containingCollenia, Cryptozoa and other organisms, accumulated on top of the eroded older Precambrian metamorphics and granitic rocks, that formed the northeast flank of the miogeosynclinal part of the ancestral North American Cordilleran Geosyncline, representing a near-shore facies. These rocks deformed together with the overlying Paleozoic sedimentary rocks at the end of the Paleozoic, during the Sonoran Orogeny.The present abrupt truncation in the west of both the older and youngest Precambrian rocks in northwest Mexico against the Gulf of California, is the result of the combination of late Paleozoic movements along the Texas Lineament and Torreón-Monterrey Fracture Zone, of the regeneration due to Early Jurassic metamorphism and anatexis, and of movements along the late Mesozoic-Tertiary San Andreas Fault System. A similar truncation of the younger Precambrian rocks in southern Mexico against the Pacific Ocean crust, is considered to be result of a combined thrust and left-lateral movement along the Jalisco-Nicoya Fault during medial Tertiary time.
Zusammenfassung Nach dem augenblicklichen Stand der geologischen Kartierung gibt es drei Haupteinheiten präkambrischer Gesteine in Mexiko. Die ältesten (> 1700 M. J.) und die jüngsten (< 700 M. J.) sind auf den Nordwestteil des Landes beschränkt, während die mittlere Einheit (1300-800 M. J.) in Ost- und Südmexiko vorkommt und sich bis nach Nord-Guatemala erstreckt.Die Gesteine der ältesten Serie - Grauwacken und vulkanische Gesteine — wurden vor mehr als 1700 M. J. in einer Eugeosynklinale abgelegt, die nach Mexiko von NNE her hineinreichte, wo sie einen noch älteren Kraton begrenzte. Vor etwa 1700 M. J. wurden diese Gesteine der Metamorphose und Anatexis unterzogen; daraus resultierte die Amphibolit-Granulit-Fazies, die Platznahme von Granitstöcken und Batholiten.Eine ähnliche Geschichte hatten die jüngeren präkambrischen Gesteine Ostund Süd-Mexikos. Hier wurden, beginnend etwa vor 1300 M. J., in der südlichen Fortsetzung der Grenville-Geosynklinale Grauwacken und vulkanische Gesteine abgelagert. Vor 1000-900 M. J. fanden Metamorphose und Anatexis statt, und der Oaxacan-Strukturbogen entstand.Granitischer Magmatismus fand vor etwa 700 M. J. im äußersten Nordwesten Mexikos (ebenfalls südöstlich von Mexiko) statt, der in Texas bisher nicht nachgewiesen wurde. Ihm folgten Diabasintrusionen; nach denen kam es zur Ablagerung jüngster präkambrischer Sedimente.Im jüngsten Präkambrium wurde in NW-Mexiko eine etwa 2000 m mächtige Serie von Konglomeraten, sandigem Tonstein und Dolomit (Collenia, Cryptozoa und andere Organismen enthaltend) abgelagert, und zwar diskordant auf älter präkambrischen metamorphen und granitischen Gesteinen. Sie bildeten in Küstenfazies die Nordostflanke des miogeosynklinalen Teiles der angestammten nordamerikanischen Kordilleren-Geosynklinale. Sie wurden zusammen mit den überlagernden paläozoischen Sedimenten am Ende des Paläozoikums gefaltet (Sonoran-Orogenese).Das heutige plötzliche Aufhören der älteren und der jüngsten präkambrischen Gesteine Nordwest-Mexikos im Westen gegen den Golf von Kalifornien ist das Ergebnis der Kombination von spätpaläozoischen Bewegungen entlang dem Texas-Lineament und der Torreón-Monterrey-Bruchzone (s. Abb. 11), ihrer Regeneration während frühjurassischer Metamorphose bzw. Anatexis und von Bewegung entlang der spätmesozoisch-tertiären San-Andreas-Bewegung. Ein ähnliches Aufhören der jüngeren präkambrischen Gesteine in Süd-Mexiko gegen die Kruste des Pazifiks gilt als das Ergebnis gleichzeitiger Überschiebung und linksseitlicher Seitenverschiebung im mittleren Tertiär entlang der Jalisco-Nicoya-Verwerfung.
Resumen El estado actual de la cartografía geológica indica que existen tres unidades principales de rocas precámbricas en México. La unidad más antigua (más antigua que 1,700 m. a) y la más reciente (más reciente que 700 m. a.) se limitan para la parte noroccidental del país. La unidad intermedia (1,300-800 m. a.) se encuentra en las partes oriental y meridional de México, y se extiende a la parte septentrional de Guatemala.Las rocas, que constituyen la unidad más antigua, se acumularon como grauvacas y rocas volcánicas relacionadas en un eugeosinclinal, antes de 1,700 m. a.; este eugeosinclinal se extendió a México desde el norte-noreste, donde rodeó un cratón precámbrico aún más antiguo. Estas rocas sufrieron metamorfismo y anatexis cerca de 1,700 m. a., procesos que produjeron el desarrollo de la facies de anfibolita-granulita y el emplazamiento de troncos y batólitos graniticos.Una historia similar, aunque algo más reciente, registran las rocas precámbricas en las partes oriental y meridional de México. Estas rocas acumularon en la prolongación meridional del Geosinclinal Grenville, como grauvacas y rocas volcánicas, a partir, hace aproximadamente de 1,300 m. a. Estas rocas pasaron por metamorphismo y anatexis durante el período comprendido entre 1,000 y 900 m. a., para formar la Faja Tectónica Oaxaqueña.Un evento de magmatismo granítico, ocurrido hace cerca de 700 m. a., se manifiesta en los extremos noroccidental y suroriental de México, y el cual aún no se ha identificado en Texas. En el noroeste, este evento fue seguido por la intrusión de diques de diabasa, antes del depósito de los sedimentos precámbricos de los más recientes.Durante el Precámbrico lo más tardío, en el noroeste de México, se acumuló una sequencia de cerca de 2,000 m de espesor, encima de las rocas metamórficas y graníticas precámbricas más antiguas profundamente erosionadas que formaron en flanco nororiental de la parte miogeosinclinal del ancestral Geosinclinal Cordillerano de Norte América; la secuencia consiste en conglomerado, lutita arenosa, y dolomita conCollenia, Cryptozoa, y con otros organismos, representando una facies cercana a la costa.La terminación actual abrupta occidental de las rocas precámbricas más antiguas y las más recientes en el noroeste de México contra el Golfo de California, es el resultado de movimientos paleozoicos tardios a lo largo del Almeamiento de Texas y de la Zona de Fracturamiento Torreón-Monterrey, de la regeneración producida por el rnetamorfismo y anatexis durante el Jurásico Temprano, y de movimientos a lo largo del Sistema de Fallas San Andreas durante el Mesozoico tardío-Terciario. Un truncamiento similar de las rocas precámbricas más recientes en el sur de México contra la corteza del Océano Pacífico, se considera como resultado tanto de movimiento lateral sinistral como de cabalgamiento a lo largo de la Falla Jalisco-Nicoya, durante el Terciario medio.
1 : (h700 ) ( 700 ) - ; (1300-800 ) . — — 1700 , NNE . 1700 , - , . . , 1300 Grenville . 1000-900 n. 700 - ( - ) , . , . NW – 2000 — , ( Collenia, Cryptozoa ). - . . - Terreon-Monterrey (p . 12), - , -- San-Andreas. , Jalisco-Nic.

Publication authorized by the Director of Instituto de Geologia, Universidad Nacional Autónoma de México.  相似文献   

11.
The neotectonic movements on the Balkan Peninsula occurred after the last intense thrusting (Early Miocene), and after the Early — Middle Miocene planation. They were controlled by extensional collapse of the Late Alpine orogen, and by extension behind the Aegean arc, and were influenced by the complicated vertical and horizontal movements in the Pannonian region. The Stara-planina and Dinarian-Hellenic linear neotectonic morphostructures inherited the Alpine orogenic zones (Balkanides and Dinarides-Hellenides) and bounded the Central-Balkan neotectonic region. The linear morphostructures were tilted towards the Pannonian and Euxinian basins and the North-Aegean trough.The Central-Balkan neotectonic region has a complicated block structure (horst-and-graben pattern) dominated by the NNW-SSE Struma and Vardar lineaments, the WNW-ESE Sava and Marica lineaments, and the Middle-Mesta and North Anatolian fault zones. The dominating Serbo-Macedonian neotectonic swell was rifted, and subsided along the Struma and Vardar lineaments. The range of the vertical neotectonic displacements reached a maximum of 3–4 km, and even up to 6 km at the edges of the Pannonian and Aegean basins. The general doming of the region was controlled by the isostatic uplift of a thickened crustal lens (Rhodope Massif) in the southern margin of the Eurasian plate. The collapse of the complicated domal structure began along the main (Struma, Vardar and Marica) lineaments in the central parts of the dome, and continued in the Pliocene and Quaternary along a more external contour bounded by the Stara-planina and Dinarian-Hellenic linear morphostructures.
Zusammenfassung Die neotektonischen Bewegungen der Balkan-Halbinsel begannen nach den letzten intensiven Überschiebungen (frühes Miozän) und nach der frühbis mittelmiozänen Verebnung. Gesteuert wurden die Bewegungen durch den Dehnungskollaps des spätalpinen Orogens, der Dehnung hinter dem Ägäischen Bogen und den komplizierten vertikalen und horizontalen Bewegungen in der pannonischen Region. Die neotektonische Region des Zentralbalkans liegt zwischen den linearen, neotektonischen Morphostrukturen der Strara-planina und der Dinariden-Helleniden. Sie übernahmen die alpidischen Orogenzonen der Balkaniden und Dinariden-Helleniden und wurden zum Pannonischen-, dem Präkarpatischen- und dem Nordägäischen Trog geneigt.Die Region zeigt einen komplizierten Blockaufbau (Horst- und Grabenstrukturen), der von den NNW-SSE streichenden Struma- und Vardar-Lineamenten, von den WNW-ESE verlaufenden Sava- und Marica-Lineamenten und der Mittelmesta- und der Nordanatolischen Bruchzone dominiert war. Die Serbo-mazedonische neotektonische Schwelle war von Bruchspaltenbildung und Absenkung parallel der Struma- und Vardar-Lineamente betroffen. Die Höhe der vertikalen Versatzbeträge erreichte ein Maximum von 3–4 km; an den Rändern des Pannonischen und Ägäischen Beckens sogar mit bis zu 6 km. Die allgemeine Aufwölbung der Region wurde durch isostatische Hebung der verdickten Krustenteile (Rhodopisches Massiv) am Südrand der Eurasischen Platte bedingt. Der Kollaps der komplizierten Domstruktur begann in dessen Zentralteil entlang der Hauptlineamente (Struma-, Vardar- und Marica-Lineament) und setzte sich, während des Pliozäns und Quartärs, in den peripheren Bereichen, parallel zu den äußeren Begrenzungen (Balkaniden, Dinariden-Helleniden) der linearen Morphostrukturen, fort.
Résumé Les mouvements néotectoniques dans la péninsule balkanique ont eu lieu après les derniers charriages d'âge miocène inférieur et la pénéplanation du Miocène inférieur et moyen. Ils ont été régis par l'affaissement extensionnel de l'orogène alpin tardif, par l'extension derrière l'arc égéen et par les mouvements verticaux et horizontaux complexes dans la région panonnienne. La région néotectonique centrebalkanique est située entre les morphostructures néotectoniques linéaires de Stara-Planina et des Dinarides-Hellénides. Celles-ci sont héritées des zones orogéniques alpines des Balkanides et des Dinarides-Hellénides et ont été inclinées vers les bassins panonnien, euxinien et nord-égéen.La région possède une structure en blocs (horsts et grabens) compliquée, dominée par les linéaments NNW-SSE de Struma et du Vardar, les linéaments WNW-ESE de Sava et de Marica et les zones faillées de Moyenne Mesta et d'Anatolie du nord. La ride néotectonique serbo-macédonienne a subi rifting et subsidence au long des linéaments de Struma et du Vardar. Les déplacements néotectoniques verticaux ont atteint 3 à 4 km au maximum, et même 6 km dans les bordures des bassins panonniens et égéen. Le soulèvement en dôme de la région a été provoqué par la montée isostatique d'une portion épaissie de l'écorce (massif du Rhodope) dans la marge méridionale de la plaque eurasiatique. L'affaissement de cette structure en dôme complexe a commencé le long des linéaments principaux (de Struma, Vardar et Marica) dans les parties centrales du dôme et a continué pendant le Pliocène et le Quaternaire le long d'un contour plus externe limité par les morphostructures néotectoniques linéaires de Stara-Planina et dinarohellénique.
( ) -, . , . - . - , - . NNWSSO, WNW-OSO . - . 3–4 , 6 . . ( , ) , , .
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12.
Temperatures of the formation of mud-volcanic waters are determined based on concentrations of some temperature-dependent components (Na–Li, Mg–Li). Estimates obtained for the Taman and Kakhetia regions are similar and range from 45 to 170°, which correspond to depths of 1–4.5 km. The calculated temperatures correlate with the chemical (Li, Rb, Cs, Sr, Ba, B, I, and HCO3) composition of water and 13 (2) and 13 (CH4) values in spontaneous gases. The isotope values indicate that mechanisms of the formation of 13-rich gases, i.e., gases with high 13 values (up to +16.0 in 2 and –23.4 in CH4) in mud-volcanic systems of Taman and Kakhetia are governed by fluid-generation temperatures rather than the supply of abyssal gases. The 11 value was determined for the first time in mud-volcanic products of the Caucasus region. This value ranges from +22.5 to +39.4 in the volcanic water of Georgia, from –1.2 to +7.4 in the clayey pulp of Georgia, and from –7.6 to +13.2 in the clayey pulp of Taman. It is shown that the 11 value in clay correlates with the fluid-generation temperature and 11 correlates with 13 in carbon-bearing gases. These correlations probably testify to the formation of different phases of mud-volcanic emanations in a single geochemical system and suggest the crucial role of temperature in the development of isotope-geochemical features.  相似文献   

13.
Zusammenfassung Im Devon der nördlichen Sierra Morena und der Sierra de San Pedro treten Schichtlücken auf, die in den untersuchten Mulden ein unterschiedliches Ausmaß erreichen. Das Mitteldevon konnte nirgends nachgewiesen werden. Das Oberdevon folgt unmittelbar über unterdevonischen oder auch silurischen Schichten. Im südlichen Arbeitsgebiet kann sogar das Oberdevon fehlen, so daß unterkarbonische Sedimente über silurischen und älteren Schichten liegen.Für das Fehlen von Oberdevon kann Schwellenbildung und damit verbundene Abtragung vermutet werden. Die Schichtlücken im Unter- und Mitteldevon der übrigen Gebiete scheinen dagegen durch Unterbrechung der Sedimentzufuhr erklärbar zu sein.
In the Devonian of northern Sierra Morena and Sierra de San Pedro there exist stratigraphical breaks of different amount in the investigated troughs. No Middle Devonian could be found. Upper Devonian rests directly upon Lower Devonian or Silurian rocks. Due to the occasional lack of Upper Devonian in the southern area under discussion even sediments of Lower Carboniferous age may superpose Silurian and older deposits.The absence of Upper Devonian is supposed to be caused by development of ridges and their erosion. However, stratigraphical breaks during Lower and Middle Devonian in the other areas seem to be explicable by non-deposition.
Résumé Dans les synclinals étudiés du Dévonien de la Sierra Morena septentrionale et de la Sierra de San Pedro il y a des lacunes stratigraphiques atteignant de différentes ampleurs. Dévonien moyen ne fut nulle part observé. Dévonien supérieur suit immédiatement les couches du Dévonien inférieur ou bien du Silurien. Dans le secteur méridional il y a même des lacunes stratigraphiques du Dévonien supérieur, et les sédiments du Carbonifère inférieur reposent sur le Silurien ou sur des couches plus anciennes.Il est possible qu'un soulèvement d'un paléorelief accompagné de l'érosion soit responsable de la lacune du Dévonien supérieur. Quant aux lacunes du Dévonien inférieur et moyen des autres régions elles sont plutôt à expliquer par non-déposition.
(). . , . , , , .
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14.
Compositions of basaltic samples from the southeastern Brazil passive margin (18°–24° S) depict the change from continental to oceanic lithosphere during the opening of the South Atlantic Ocean. Samples studied range from 138 to 105 m.y. old and are from 12 Petrobrás drill cores recovered from the coastline to about 150 km offshore in the Espirito Santo, Campos, and Santos basins. Compositions vary, ranging, for example, from 49–54 wt.% SiO2, 0.5–3.0 wt.% TiO2, 0.6–5.0 FeO*/MgO, and 1-6 La/ Yb(n), but can be grouped: (i) basalts enriched in incompatible elements, such as K (some K2O>2.0 wt.%), Rb (>18 ppm), Zr (>120 ppm), and LREE (some FeO* 16 wt.%; most with SiO2 51–54 wt.%), and resembling Serra Geral continental flood basalts (SG-CFB) of southern Brazil; (ii) basalts less enriched, or transitional, in incompatible elements, having K2O <0.40 wt.% and flat REE patterns, and resemble N. Atlantic diabases and FAMOUS basalts; and (iii) one depleted sample, Ce/Yb(n)=0.7, where Ce(n)=4. Expressed in oceanic-basalt terminology and Zr-Nb-Y abundances, enriched samples are P- and T-type MORB (e.g., Zr/Nb 4–25), transitional samples are T-type (Zr/ Nb 8–27), and the depleted sample is N-type MORB (Zr/Nb>30).Trace-element ratios (e.g., Zr/Nb, Zr/Y) link the Brazil margin basalts to a heterogeneous mantle (attributed to metasomatic veining) of variably proportioned mixtures of depleted-mantle (N-MORB) and plume (P-MORB, e.g., Tristan hotspot) materials. The various compositions therefore reflect, in part, different zones of melting during the separation of Gondwanaland, where gradual decompression during rifting enabled concurrent melting of upper, more depleted (non- or sparsely-veined) mantle and enriched (densely-veined) mantle. Within the time represented, melting produced enriched, transitional, and depleted magmas that were emplaced subaerially, hypabyssally, and subaqueously; they mark the transition from CFB before rifting and separation (from deeper, enriched mantle) to N-MORB in the S. Atlantic afterwards (from non- or sparsely-veined upper mantle). While P-type mantle components account for the enriched compositions of some basalts (Zr/Nb<8), continental crust is largely responsible for that of others (e.g., Ti/Zr 40–57; La/Yb(n) 5–6, and 18O+12.2 in one sample). Some may be contaminated expressions of otherwise T-type basalts free of crustal components. This study identifies CFB to be from sources similar to those for T- and P-type oceanic rocks, where individual CFB magmas may or may not have acquired crustal signatures.  相似文献   

15.
Chemical data for pelitic rocks (shallow-marine platform sediments) of the 2.9 Ga old Pongola Supergroup, South Africa, and the 550–700 Ma old Nama Group, Namibia, revealed clearly different compositions in both groups. A comparison of the Pongola and Nama data with literature values for sedimentary rocks shows a trend for Cr/TiO2 and Cr/Zn ratios as well as the absolute Cr and Ni concentrations to lower values with decreasing age, whereas the Cr/Ni ratios seem to remain broadly constant through time. REE patterns of Pongola and Nama sediments show no significant difference, thus giving the impression of a post-Archaean origin for the demonstrably Archaean Pongola sediments. However, a plot of the trace element data for these sediments, normalized to the average shale of TuRekian &Wedepohl (1961) shows the Pongola shales to have a clear Archaean pattern whereas the Nama pelites display a typical post-Archaean signature. The results of this investigation confirm a model of rapid evolution of the Earth's upper continental crust from a predominantly mafic composition in the early Archaean to a more felsic character with increasing differentiation. The geochemistry of post-Archaean sediments may reflect the onset of cannibalistic recycling of older crust as proposed byVeizer (1973) and the end of major crustal growth.
Zusammenfassung In der vorliegenden Arbeit werden zwei Plattformsedimente (marine Flachwasserablagerungen) verschiedenen Alters (Pongola 2.9 Mrd. Jahre, Südafrika, Nama 550–700 Mio. Jahre, Südwest Afrika/Namibia) chemisch analysiert und miteinander verglichen. Analysen der Tonmineralfraktion sollten zusätzliche Informationen bereitstellen.Die Pelite der Pongola und Nama Gruppen lassen sich statistisch und nach geochemischen Parametern in Cluster unterteilen. Diese Cluster unterscheiden sich nur gering auf Grund ihrer Hauptelementanalysen, die Spurenelemente hingegen weisen einen altersabhängigen Trend auf. Ganz deutlich kommt dies bei den Cr-Werten zum Ausdruck. Von 545 ppm in dem ersten Cluster der ältesten Gesteine fällt er auf etwa 55 ppm in dem zweiten Nama Cluster der jüngsten Gesteine ab. Um die Entwicklungstendenzen darstellen zu können, wurden X/Y-Diagramme erstellt. Es stellte sich heraus, daß für Proben aus dem südlichen Afrika der Chromgehalt mit jünger werdendem Alter abnimmt. Zn und Ni zeigen deutlich, wie sehr diese Elementkonzentrationen in Sedimenten durch einen langen Transportweg und eine intensive Aufarbeitung beeinflußt werden können. Ein Vergleich der Pongola und Nama Daten läßt den Schluß zu, daß die Seltenen Erden nicht unbedingt zur Unterscheidung archaischer von post-archaischen Sedimente geeignet sind.Die Abnahme der Cr/TiO2- und der Cr/Zn-Verhältnisse sowei der absoluten Cr- und Ni-Konzentrationen mit abnehmendem geologischen Alter der Sedimente deuten auf eine rasche Entwicklung (von ca. 3.3 Mrd. J. bis ca. 2.3 Mrd. J.) von einer zunächst vorwiegend mafischen oberen Erdkruste zu einer zunehmend felsischen (d. h. stärker differenzierten) Kruste hin. Die relativ geringen Veränderungen in späterer Zeit (d. h. < 2.3 Mrd. J.) lassen auf den Beginn einer Aufarbeitung schon vorhandener Sedimente (recycling) und eine nur untergeordnete Bildung neuer kontinentaler Erdkruste schließen.
Résumé L'objet de ce travail est de comparer les compositions chimiques de la fraction pélitique (< 2) dans des sédiments de plate-forme, déposés en mer peu profonde, et appartenant respectivement au supergroupe de Pongola (± 2.9 G.a., Afrique du S) et au groupe de Nama (550–700 M.a., Namibie).Cette comparaison, menée par la méthode statistique des «clusters analysis», ne révèle pas de différence entre les deux groupes, en ce qui concerne les éléments majeurs. Pour les éléments en traces, par contre, on constate avec l'âge décroissant des roches une diminution des rapports Cr/TiO2, Cr/Zn ainsi que des teneurs en Cr et en Ni, tandis que le rapport Cr/Ni reste sensiblement constant.Les distributions des terres rares des deux groupes ne présentent pas de différence significative, donnant l'impression d'un âge post-archéen pour les sédiments du groupe de Pongola (2.9 G.a.). Toutefois, le report de données des éléments en traces, normalisées par rapport au shale moyen deTurekian etWedepohl (1961) montre nettement des distributions archéennes pour le groupe de Pongola et post-archéennes pour le groupe de Nama.Ces investigations confirment le modèle d'une évolution rapide de la croûte continentale supérieure depuis une composition mafique à l'Archéen ancien (3.3 G.a.) vers un caractère plus felsique, c'est-à-dire plus différencié vers 2.3 G.a., le peu de changement au cours des périodes ultérieures (< 2.3 G.a.) indiquant un recyclage continuel des mêmes matériaux sans intervention notable d'un accroissement de la croûte continentale.
( 2,9 , — 550–700 ), , . , , . , . . 545 55 . , , . . , - . , ( 3,3 2.3 ) , . . . . . 2.3 , , . . recycling, .
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16.
Zusammenfassung Der primare klastische Anteil des mittleren Muschelkalks besitzt ein Maximum in den Korngrößen von 6–20, Ø , das über weite Strecken konstant bleibt. Der Mineralgehalt besteht aus Quarz, Feldspat, Glimmer und vielleieht Kaolinit.Bei der Diagenese warden Quarz und Feldspat teils korrodiert, teils wurden Quarz und Albit neu gebildet. In Randgebieten entstand Glaukonit vermutlich aus Glimmern.Durch Grundwassereinwirkung bildete rich ein zweites Maximum zwischen 0–2 Ø aus. Dabei ist in diesen Korngrößen eine Zunahme an Illit und Kaolinit und das Neuauftreten von Montmorillonit zu verzeichnen.Bei der Verwitterung verschwand das Maximum zwischen 6–20 Ø zugunsten eines Maximums zwischen 0–2 Ø . Damit verschwand auch der primäre Mineralgehalt fast völlig. Die Fraktionen unter 2 Ø setzen sich aus einem illitähnlichen Mineral zusammen.Durch Grundwassertätigkeit und Oberflächenverwitterung wurde also nicht nur der lösliche Anteil des mm ausgelaugt, sondern es sind auch deutliche Veränderungen des klastischen Anteils wahrzunehmen.Herrn Professor Dr.Carl W. Correns zum 60. Geburtstag gewidmet.  相似文献   

17.
Generalized development of calc-silicate bands in several alpujarride units of the central and western segments of the Betic Zone, is interpreted as the result of metamorphic differentiation from original calcium-rich sedimentary beds in the sequence. Presence of Scapolite suggests that this phenomenon may have been made possible by the catalizing action of high anion concentrations in the pore fluid medium during metamorphism, probably caused by the existence of evaporic material in the original sediments. This hypothesis, which is further supported by anomalous high Ca, Na and K contents of the enclosing metapelites, leads to the correlation of the present calc-silicate bearing metamorphic formations with well-known permo-werfenian evaporitic series in other units of the Betic Zone. The use of this new criterion of stratigraphic correlation would indicate that highly metamorphosed permo-triassic sequences have often been misidentified as more ancient formations, thus causing an underestimation of the importance of alpine HT-LP metamorphism in the alpujarride tectonic domain.
Zusammenfassung Das häufige Auftreten von Kalksilikatbändern (manchmal mit Skapolith) in einigen alpujarriden Einheiten, besonders im zentralen und westlichen Abschnitt der betischen Kordillere, wird erklärt als Ergebnis einer metamorphen Differentiation von ursprünglich Ca-reichen Schichten. Die Anwesenheit von Skapolith legt eine hohe Anionenkonzentration der intergranularen fluiden Phasen während der Metamorphose nahe, bedingt durch evaporitisches Material der ursprünglichen Sedimente. Diese Hypothese, zusätzlich gestützt durch den extrem hohen Gehalt der umgebenden Pelite an löslichen Kathionen (Ca, Na, K), erlaubt die Korrelation der Kalksilikatbänder-haltigen Formationen mit aus anderen betischen Einheiten bekannten evaporitischen Serien des Permowerfenïan. Auf die stratigraphische Korrelation angewendet, legt dies nahe, daß öfters hochmetamorphe, permotriadische Serien fälschlicherweise als älter betrachtet wurden, was zu einer Unterschätzung der alpinen Metamorphose (Niederdruck-Hochtemperatur) im alpujarridem Bereich führte.
Resumen El desarrollo bastante generalizado de bandas de silicatos calcicos, entre los cuales se encuentra a veces una escapolita, en varias unidades alpujárrides de los segmentos central y occidental de la Zona Bética, es interpretado como el resultado de un proceso de diferenciación metamórfica a partir de lechos sedimentarios originalmente ricos en calcio. La presencia de escapolita sugiere que este hecho ha sido probablemente posible gracias a la existencia de una alta concentración de aniones en el fluido metamórfico intergranular, condicionada por la existencia de material evaporitico en los sedimentos originales. Esta última hipótesis que es ulteriormente apoyada por un contenido anómalamente alto de cationes solubles (Ca, Na, K) en las metapelitas encajantes, permite correlacionar las formaciones que contienen los lechos de silicatos calcicos con conocidas series evaporiticas de edad permowerfenense en otras unidades de la Zona Bética. La aplicación de este nuevo criterio de correlación estratigráfica sugiere que series permotriásicas altamente metamorfizadas han sido a menudo erróneamente interpretadas como más antiguas, hecho que ha conllevado a una substimación de la importancia del metamorfismo (BP-AT) alpino en el dominio tectónico alpujárride.
Résumé Le developpement très fréquent de roches litées à silicates calciques dans quelques unités alpujarrides des regions centrale et occidentale de la Zone Bétique, est interpreté comme la conséquence d'un processus de différenciation métamorphique à partir de lits riches en calcium dans les sequences sédimentaires originelles. La présence de scapolite suggére que ce phénomène a été rendu possible par l'intervention d'un cataliseur naturel, tel que des hautes concentrations en anions dans le milieu fluide intergranulaire pendant le métamorphisme, occasionées probablement par l'existence de materiel évaporitique dans les sédiments originels.Cette hypothese, qui se trouve additionellement supportée par des teneurs élevées en cations solubles des métapelites encaissantes, permet d'assimiler les formations qui contiennent les lits à silicates calciques avec des séries évaporitiques permowerféniennes, bien connues dans d'autres unités des zones internes des Cordilléres Bétiques. L'application de ce nouveau critère de corrélation stratigraphique indiquerait que des séquences permotriasiques fortement affectées par le métamorphisme ont été souvent à tort interprétées comme plus anciennes, amenant ainsi a une sous-estimation de l'importance du métamorphisme alpin (BP-HT) dans le domaine tectonique alpujarride.
- — — , , , , . , . , : , Na, , , - Permowerfenian, . , - , — — .
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18.
Comparison between two types of multifractal modeling   总被引:1,自引:0,他引:1  
The interrelationships between two previously developed multifractal models are discussed. These are the Evertsz-Mandelbrot model developed on the basis of the multifractal spectrum f(), and the Schertzer-Lovejoy model based on the codimension function C() where and represent Hölder exponent and field order, respectively. It is shown how these two models are interrelated: they are identical for values of within the range D–(0)D–min. where D is the Euclidean dimension. For D–maxD–(0), however, f() remains a continuous function of whereas C() assumes constant value. In this respect, the fractal spectrum f() can provide more information about the multifractal measure than the codimension function C(). The properties of the two models are illustrated by application to the binomial multiplicative cascade model.  相似文献   

19.
A third type of transition zones from oceanic to continental crust here called Columbian, is proposed, in addition to the two more commonly known types. Subsidence of the Earth's crust, typical of all transition zones, is shown to be connected (by geophysical properties) with the transformation of continental crust into intermediate crust and later into oceanic. The most likely mechanism of such changes is the basification of continental crust, its foundering, block by block, into the heated upper mantle, and its substitution by the new oceanic crust. The evolution of transition zones of Pacific type is largely influenced by deep faults, which reach down to the level of undepleted mantle; from this level to the surface the volatile products rise as the essential means of formation of calc-alkali magmas on island arcs. Benioff zones are deep faults whose inclination is secondary and connected with the density contrast in the upper mantle on either side of the Benioff zone. The denser mantle flows under less dense mantle, whereas the subduction phenomenon, as depicted by plate tectonics, is nonexistent.On the whole, the evolution of transition zones tends towards growth of the oceans at the expense of the continents, but oceanic crust thickens by addition of volcanogenic layers of andesitic composition in transition zones of Pacific type, on island arcs of the Second type.
Zusammenfassung Den Übergangszonen zwischen ozeanischer und kontinentaler Kruste, die bisher in zwei Typen eingeteilt wurden, wird eine dritte hinzugefügt. Diese wird hier Kolumbische Übergangszone genannt. Es wird gezeigt, daß Subsidenz der Erdkruste, typisch für alle Übergangszonen, verbunden ist mit der Transformation kontinentaler Kruste in intermediäre und schließlich in ozeanische Kruste. Der wahrscheinlichste Mechanismus für diese Veränderungen ist die Sockelbildung der kontinentalen Kruste, ihr blockweises Eingehen in den heißen Oberen Mantel und schließlich ihre Umwandlung in neue ozeanische Kruste.Die Evolution der Übergangszonen vom pazifischen Typ ist stark beeinflußt durch tiefgreifende Störungen, die bis in den Mantel reichen. Von diesem Niveau steigen die beweglicheren Produkte als die wesentlicheren Anteile der Kalkalkali-Magmen an Inselbögen auf bis hin zur Oberfläche.Benioff-Zonen sind tiefgreifende Störungen, deren Einfallen sekundär und an die Dichte Unterschiede innerhalb des Oberen Mantels auf ihren beiden Seiten gebunden ist. Die dichteren Mantelanteile fließen unter die weniger dichten, wohingegen das Phänomen der Subduktion, wie es im Rahmen der Plattentektonik dargestellt wird, nicht existiert.Die Evolution der Übergangszonen tendiert im großen und ganzen zur Ausbreitung der Ozeane auf Kosten der Kontinente. Die ozeanische Kruste verstärkt sich in den Übergangszonen des pazifischen Typs durch Anbau vulkanogener Lagen mit andesitischer Zusammensetzung.
Résumé Aux zones de transition entre la croûte continentale et la croûte océanique, jusqu'à présent ramenées à deux types, s'en ajoute une troisième, ici dénommée»Zone de transition colombienne«. On montre ici que la subsidence de l'écorce terrestre, typique pour toutes les zones de transition, est reliée (par des propriétés géophysiques) à la transformation de la croûte continentale en une croûte intermédiaire et ensuite océanique. Le mécanisme le plus probable de ces changements consiste dans la basification de la croûte continentale, son effondrement bloc après bloc dans le manteau supérieur rechauffé, et sa substitution par la nouvelle croûte océanique. L'évolution des zones de transition de type Pacifique est largement influencée par des failles profondes descendant jusqu'au niveau du manteau intact, niveau à partir duquel les produits volatiles montent vers la surface, en temps qu'éléments essentiels pour la formation des magmas calco-alcalins dans les arcs insulaires. Les zones de Benioff sont des failles profondes dont l'inclinaison est secondaire, et en liaison avec les contrastes de densité dans le manteau supérieur de chaque côté de la zone Benioff. Le manteau plus dense s'écoule sous le manteau moins dense, étant entendu que le phénomène de subduction, tel que le décrit la tectonique de plaques, est inexistant. — Dans l'ensemble, l'évolution des zones de transition tend vers la croissance des océans aux dépens des continents, tandis que la croûte océanique s'épaissit par addition des couches volcanogènes de composition andésitique dans les zones de transition de type Pacifique, sur les arcs insulaires du second type.
, . , ( ) . , ( ) . , , , . , . , , , . , .
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20.
Zusammenfassung Ein Teil der Mitteldeutschen Schwelle (R.Brinkmann 1948), der Spessart, wird sowohl bezüglich seines Innenbaues (Tektonik, Stratigraphie, Petrogenese des Grundgebirges), als auch bezüglich seiner Funktion als Lieferant für die jungpaläozoisch-mesozoischen Sedimente des Wetterau-Beckens betrachtet.Über diese Betrachtungen hinaus lassen sich Vergleiche zu anderen Gebieten der Mitteldeutschen Schwelle durchführen.Ganz offenbar ist die Grenzzone zwischen Saxothuringischer und Rhenoherzynischer Zone des Varistischen Gebirges in Mitteleuropa keine zufällige Ortslage für die Mitteldeutsche Schwelle und das Saar-Nahe-(Wetterau-)Becken. - Diese Kristallinzone hat tatsächlich zu verschiedenen Zeiten in der Erdgeschichte umgebungsdifferente Bewegungsimpulse erfahren. Sie ist darüber hinaus ohne Zweifel ein krustenversteifendes Element, was sich bereits mindestens aus ihrer modifizierenden Wirkung auf die großen Bruchsysteme der Mittelmeer-Mjösen-Zone im Bereich des nördlichen Oberrheingrabens und der südlichen Hessischen Senke ablesen läßt.
The Spessart, as part of the Central German geanticline (Mitteldeutsche Schwelle, R.Brinkmann 1948) is discussed with respect to both its internal structure (tectonics, stratigraphy, petrogenesis of the basement) and its importance as a source region of Upper-Paleozoic-Mesozoic sediments which were deposited in the basin of the Wetterau. This leads to comparisons with other regions of the Central German geanticline.Obviously the regional situation of the Central German geanticline as well as the basins along Saar and Nahe(-Wetterau) between the hercynian zones of Saxothuringia and Rhenohercynia in Central Europe is not chance.The basement belt actually has been affected to vertical movements several times during its geologic history. Apart from this this belt is a consolidating element for the crust. This can clearly be seen by watching the great fault systems which can be traced from the Mediterranean to the Norwegian Lake Mjösen (Mittelmeer-Mjösen-Zone). They are modified by the Central German geanticline in the north of the Upper Rhine Valley and in the southern low-lands of Hesse.
Résumé Une partie du bombement de l'Allemagne centrale (R.Brinkmann 1948), le Spessart, est étudiée tant sous l'aspect de sa structure interne (tectonique, stratigraphie, pétrogenèse du socle cristallin) que sous celui de son rôle comme domaine nourricier en sédiments du bassin Wetterau, du Paléozoïque supérieur au Mésozoïque.Partant de ces considérations, on peut faire des comparaisons avec d'autres régions du bombement de l'Allemagne centrale. Il est tout-à-fait évident que la zone limitrophe comprise entre les zones saxothuringienne et rhénohercynienne de la chaîne varisque de l'Europe Centrale n'est pas quelconque par rapport au bombement de l'Allemagne centrale et au bassin de la Sarre et de la Nahe (-basin de Wetterau). Cette zone cristalline a effectivement subi à différentes époques de l'histoire terrestre des mouvements distincts de ceux de son entourage. En outre elle constitue sans doute un élément qui a raidi la croûte terrestre, ce qui apparaît par l'influence modificatrice qu'elle a exercé dans la région septentrionale du Fossé du Rhin supérieur et de la dépression méridionale de la Hesse sur le grand système de fractures tectoniques de la zone Mer Méditerranée-Mjösen.
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Herrn Prof. Dr. Dr. h. c.Erich Bederke zum 70. Geburtstag gewidmet.  相似文献   

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