首页 | 本学科首页   官方微博 | 高级检索  
相似文献
 共查询到20条相似文献,搜索用时 125 毫秒
1.
The plate tectonic evolution of the Alps is intimately related to the stepwise protrusion of the Atlantic ocean to the north. The South Penninic oceanic basin of the Alps is part of the spreading system of the early Atlantic ocean in the Jurassic. In the Lower Cretacous, the North Peeninic basin forms as an appendix of the Atlantic in its second stage of evolution, connected with it via the Pyrenees trough and the Bay of Biscay. Subduction in the South Penninic ocean by convergent motion of the Briançonian and the Adriatic plates leads to a first continental collision in about mid-Cretaceous time. In the Upper Cretaceous, when the Atlantic ocean protrudes between North America and Greenland, Eurasia and Africa move divergently, and there is relative quiescence in the Alps. In the Tertiary, the Atlantic ocean spreads between Greenland and Scandinavia which results in convergent motion between Eurasia and Africa and important compressional events in the Alps.
Zusammenfassung Die plattentektonische Entwicklung in den Alpen steht mit dem etappenweisen Vorstoß des Atlantischen Ozeans nach Norden in engem Zusammenhang. Das ozeanische Südpenninische Becken der Alpen ist Teil des frühen Atlantik im Jura. In der Unterkreide bildet sich das Nordpenninische Becken als Fortsatz des Atlantik in dessen zweitem Entwicklungsstadium und steht mit diesem über den Pyrenäentrog und die Biscaya in Verbindung. Annäherung der Briançonischen und der Adritischen Platte führt zu Subduktion im Südpenninischen Becken und zu einer ersten Kontinentkollision in der Mittelkreide. Zur Zeit des atlantischen Vorstoßes zwischen Nordamerika und Grönland werden Eurasien und Afrika auseinanderbewegt, und es herrscht relative Ruhe in den Alpen. Im Tertiär bahnt sich der Atlantik seinen Weg zwischen Grönland und Skandinavien; dies führt Eurasien und Afrika gegeneinander und hat bedeutende Einengung in den Alpen zur Folge.
Résumé Le développement de la tectonique de plaques dans les Alpes est rapport étroit avec la poussée par etapes de l'Océan Atlantique en direction du Nord. Le bassin océanique piémontais des Alpes est une partie de l'Atlantique originel au moment du Jurassique. C'est au Crétacé inferieur que se forme le bassin valaisan en tant qu'appendice de l'Atlantique dans son deuxième stade de développement; il se trouve par là en relation avec la fosse pyrénéenne et le Golfe de Gascogne. Le rapprochement de la plaque briançonnaise et de la plaque adriatique conduit à une subduction dans le bassin piémontais et à une premiére collision continentale au Crétacé moyen. A l'époque de la pénétration atlantique entre l'Amérique du Nord et le Groenland, l'Eurasie et l'Atlantique s'écartérent, tandis qu'il règne une période d'accalmie relative dans les Alpes. C'est au Tertiaire que l'Atlantique se fraie son passage entre le Groenland et la Scandinavie. Cela mène à la rencontre de l'Eurasie et de l'Afrique, ce qui entraîne un rétrécissement important dans les Alpes.
. - . , ë , . . . ; , .
  相似文献   

2.
Major and trace element concentrations and initial 87Sr/86Sr ratios of lavas from the Aleutian volcanic centers of Adak and Atka have been used to study the evolution of their respective lithospheric plumbing systems. The centers are within 150 km of one another and show similar overall silica ranges (47–67%), but Adak (40 km3) is smaller than Atka (200 km3). Adak's lavas are chemically and isotopically heterogeneous (87Sr/86Sr:0.70285–0.70330) and two units contain lithospheric xenoliths. The lavas of the much larger Atka, on the other hand, have much less variability in major and trace elements as well as 87Sr/86Sr (0.70320–0.70345). We suggest that these characteristics are a measure of the relative maturity and cleanliness of the lithospheric plumbing systems that supply magma to these centers. Because Aleutian volcanic centers often remain fixed for relatively long periods of time (5 m.y.), once established, magmatic passageways are repeatedly used. Young plumbing systems are relatively cool and contain large amounts of wallrock contaminant, and ascending magmas undergo contamination as well as concurrent crystallization and fractionation. With time, however, heat and mass transfer between ascending magmas and wallrock produce thermal and chemical boundary layers that insulate subsequent magmas. In effect, the plumbing system matures. The chemical heterogeneity displayed by young, dirty systems (like Adak) reflects not only the magma source but also the wallrock encountered during ascent and possibly the effects of extensive crystal fractionation. Thus, it is the petrologic data of mature, clean systems, like Atka, that yield the most direct and unambiguous information on the ultimate origin of the lavas and their near surface evolution.  相似文献   

3.
The Miocene-Oligocene volcanism of this region is part of the larger Tertiary volcanic province found throughout E. Australia. Within the S.E. Queensland region, the volcanism is strongly bimodal, and has emanated from six major centres, and many additional smaller centres. The mafic lavas (volumetrically dominant) range continuously from ne-normative through to Q-normative and are predominantly andesine-normative; Mg/Mg+Fe (atomic ratios range from 30–60; K2O ranges from 0.42–2.93%, and TiO2 from 0.81–3.6%.Phenocryst contents are low (averaging 6.7 vol.%), and comprise olivine (Fa18–75; Cr-spinel inclusions occur locally in Mg-rich phenocrysts), plagioclase (An25–68), and less commonly augite, which is relatively aluminous in lavas of the Springsure volcanic centre. Very rare aluminous bronzite occurs in certain Q-normative lavas. Groundmass minerals comprise augite, olivine (Fa33–77), feldspar (ranging from labradorite through to anorthoclase and sanidine), Fe-Ti oxides, and apatite. Within many of the Q-normative lavas, extensive development of subcalcic and pigeonitic pyroxenes occurs, and also relatively rarely orthopyroxene. Mineralogically, the ne- and ol-normative lavas, and some of the Q-normative lavas are indistinguishable, and in view of the gradations in chemistry, the term hawaiite has been extended to cover these lavas. The term tholeiitic andesite is used to describe the Q-normative lavas containing Ca-poor pyroxenes as groundmass phases.Megacrysts of aluminous augite, aluminous bronzite, olivine, ilmenite, and spinel sporadically occur within the lavas, and their compositions clearly indicate that they are not derived from the Upper Mantle. Rare lherzolite xenoliths are also found.The petrogenesis of these mafic lavas is approached by application of the thermodynamic equilibration technique of Carmichael et al. (1977), utilizing three parental mineral assemblages that could have been in equilibrium with the magmas at P and T. The models are: (a) standard upper mantle mineralogy; (b) an Fe-enriched upper mantle model (Wilkinson and Binns 1977); (c) lower crust mineralogy, based on analysed megacryst compositions. The calculations suggest that these mafic magmas were not in equilibrium with either mantle model prior to eruption, but show much closer approaches to equilibrium with the lower crust model. Calculated equilibration temperatures and pressures (for the lower crust model) range from 995°–l,391° C (average 1,192), and 7.2–16.3 kb (average 12.4). These results are interpreted in terms of a model of intrusion and magma fractionation within the crust-mantle interface region, with consequent crustal underplating and thickening beneath the Tertiary volcanic regions. Some support for the latter is provided by regional isostatic gravity anomalies and physiographic considerations.  相似文献   

4.
Nd, Sr and O isotopic data were obtained from silicic ash-flow tuffs and lavas at the Tertiary age (16–9 Ma) Timber (Mountain/Oasis Valley volcanic center (TMOV) in southern Nevada, to assess models for the origin and evolution of the large-volume silicic magma bodies generated in this region. The large-volume (>900 km3), chemically-zoned, Topopah Spring (TS) and Tiva Canyon (TC) members of the Paintbrush Tuff, and the Rainier Mesa (RM) and Ammonia Tanks (AT) members of the younger Timber Mountain Tuff all have internal Nd and Sr isotopic zonations. In each tuff, high-silica rhyolites have lower initial Nd values (1 Nd unit), higher87Sr/86Sr, and lower Nd and Sr contents, than cocrupted trachytes. The TS, TC, and RM members have similar Nd values for high-silica rhyolites (-11.7 to -11.2) and trachytes (-10.5 to -10.7), but the younger AT member has a higher Nd for both compositional types (-10.3 and -9.4). Oxygen isotope data confirm that the TC and AT members were derived from low Nd magmas. The internal Sr and Nd isotopic variations in each tuff are interpreted to be the result of the incorporation of 20–40% (by mass) wall-rock into magmas that were injected into the upper crust. The low Nd magmas most likely formed via the incorporation of low 18O, hydrothermally-altered, wall-rock. Small-volume rhyolite lavas and ash-flow tuffs have similar isotopic characteristics to the large-volume ash-flow tuffs, but lavas erupted from extracaldera vents may have interacted with higher 18O crustal rocks peripheral to the main magma chamber(s). Andesitic lavas from the 13–14 Ma Wahmonie/Salyer volcanic center southeast of the TMOV have low Nd (-13.2 to -13.8) and are considered on the basis of textural evidence to be mixtures of basaltic composition magmas and large proportions (70–80%) of anatectic crustal melts. A similar process may have occurred early in the magmatic history of the TMOV. The large-volume rhyolites may represent a mature stage of magmatism after repeated injection of basaltic magmas, crustal melting, and volcanism cleared sufficient space in the upper crust for large magma bodies to accumulate and differentiate. The TMOV rhyolites and 0–10 Ma old basalts that erupted in southern Nevada all have similar Nd and Sr isotopic compositions, which suggests that silicic and mafic magmatism at the TMOV were genetically related. The distinctive isotopic compositions of the AT member may reflect temporal changes in the isotopic compositions of basaltic magmas entering the upper crust, possibly as a result of increasing basification of a lower crustal magma source by repeated injection of mantle-derived mafic magmas.  相似文献   

5.
Holocene lavas from Craters of the Moon (COM) National Monument are representative of differentiated lavas which occur around the margins of the Snake River Plains (SRP) and they range serially in composition from alkali- and phosphorous-rich ferrobasalts to ferrolatites. Petrographic study indicates that these lavas evolved primarily by cotectic crystallization of olivine, plagioclase, magnetite and apatite in the mafic members of the suite (ferrobasalts), and by cotectic crystallization of plagioclase, magnetite, clinopyroxene and minor olivine in the salic members. Quantitative phase relations in the COM lavas, calculated by means of a leastsquares mixing program, indicate that the observed range in composition among these lavas corresponds to at least 70 percent crystallization of a magma similar to the most mafic COM lavas. Anhydrous one-atmosphere experimental crystallization studies fail to reproduce exactly the inferred phase relations; the discrepancy is attributed to the presence of water in the naturally crystallized magmas. The origin of COM parental magma cannot be unequivocably resolved. Available evidence suggests that COM lavas do not represent melts derived directly from the mantle: (1) high Sr87/Sr86 ratios (0.708 to 0.712), (2) relatively high Fe/(Fe+Mg) and excluded-element content in even the most mafic COM lavas, (3) occurrence of megacrysts of inferred high-pressure origin in the Lava Creek flow. Megacrysts occur in the Lava Creek flow as clusters of labradorite, aluminous clinopyroxene, and olivine. Analogy with the experiments of Thompson [1] and least squares mixing calculations indicate that intermediate (ca. 8 to 10 Kbar) pressure fractionation of such megacrysts from olivine tholeiite magma may yield derivative COM-type liquids.  相似文献   

6.
Previous studies of alkalic lavas erupted during the waning growth stages (<0.9 Ma to present) of Haleakala volcano identified systematic temporal changes in isotopic and incompatible element abundance ratios. These geochemical trends reflect a mantle mixing process with a systematic change in the proportions of mixing components. We studied lavas from a 250-m-thick stratigraphic sequence in Honomanu Gulch that includes the oldest (1.1 Ma) subaerial basalts exposed at Haleakaka. The lower 200 m of section is intercalated tholeiitic and alkalic basalt with similar isotopic (Sr, Nd, Pb) and incompatible element abundance ratios (e.g., Nb/La, La/Ce, La/Sr, Hf/Sm, Ti/Eu). These lava compositions are consistent with derivation of alkalic and tholeiitic basalt by partial melting of a compositionally homogeneous, clinopyroxene-rich, garnet lherzolite source. The intercalated tholeiitic and alkalic Honomanu lavas may reflect a process which tapped melts generated in different portions of a rising plume, and we infer that the tholeiitic lavas reflect a melting range of 10% to 15%, while the intercalated alkalic lavas reflect a range of 6.5% to 8% melting. However, within the uppermost 50 m of section. 87Sr/86Sr decreases from 0.70371 to 0.70328 as eruption age decreased from 0.97 Ma to 0.78 Ma. We infer that as lava compositions changed from intercalated tholeiitic and alkalic lavas to only alkalic lavas at 0.93 Ma, the mixing proportions of source components changed with a MORB-related mantle component becoming increasingly important as eruption age decreased.  相似文献   

7.
The 50 km-long West Valley segment of the northern Juan de Fuca Ridge is a young, extension-dominated spreading centre, with volcanic activity concentrated in its southern half. A suite of basalts dredged from the West Valley floor, the adjacent Heck Seamount chain, and a small near-axis cone here named Southwest Seamount, includes a spectrum of geochemical compositions ranging from highly depleted normal (N-) MORB to enriched (E-) MORB. Heck Seamount lavas have chondrite-normalized La/Smcn0.3, 87Sr/86Sr=0.70235–0.70242, and 206Pb/204Pb=18.22–18.44, requiring a source which is highly depleted in trace elements both at the time of melt generation and over geologic time. The E-MORB from Southwest Seamount have La/Smcn1.8, 87Sr/86Sr=0.70245–0.70260, and 206Pb/204Pb=18.73–19.15, indicating a more enriched source. Basalts from the West Valley floor have chemical compositions intermediate between these two end-members. As a group, West Valley basalts from a two-component mixing array in element-element and element-isotope plots which is best explained by magma mixing. Evidence for crustal-level magma mixing in some basalts includes mineral-melt chemical and isotopic disequilibrium, but mixing of melts at depth (within the mantle) may also occur. The mantle beneath the northern Juan de Fuca Ridge is modelled as a plum-pudding, with plums of enriched, amphibole-bearing peridotite floating in a depleted matrix (DM). Low degrees of melting preferentially melt the plums, initially removing only the amphibole component and producing alkaline to transitional E-MORB. Higher degrees of melting tap both the plums and the depleted matrix to yield N-MORB. The subtly different isotopic compositions of the E-MORBs compared to the N-MORBs require that any enriched component in the upper mantle was derived from a depleted source. If the enriched component crystallized from fluids with a DM source, the plums could evolve to their more evolved isotopic composition after a period of 1.5–2.0 Ga. Alternatively, the enriched component could have formed recently from fluids with a less-depleted source than DM, such as subducted oceanic crust. A third possibility is that enriched material might be dispersed as plums throughout the upper mantle, transported from depth by mantle plumes.  相似文献   

8.
The magma sources for granitic intrusions related to the Mesozoic White Mountain magma series in northern New England, USA, are addressed relying principally upon Nd isotopes. Many of these anorogenic complexes lack significant volumes of exposed mafic lithologies and have been suspected of representing crustal melts. Sm–Nd and Rb–Sr isotope systematics are used to evaluate magma sources for 18 felsic plutons with ages ranging from about 120 to 230 Ma. The possibility of crustal sources is further examined with analyses of representative older crust including Paleozoic granitoids which serve as probes of the lower crust in the region. Multiple samples from two representative intrusions are used to address intrapluton initial isotopic heterogeneities and document significant yet restricted variations (<1 in Nd). Overall, Mesozoic granite plutons range in Nd [T] from +4.2 to -2.3, with most +2 to 0, and in initial 87Sr/86Sr from 0.7031 to 0.709. The isotopic variations are roughly inversely correlated but are not obviously related to geologic, geographic, or age differences. Older igneous and metamorphic crust of the region has much lower Nd isotope ratios with the most radiogenic Paleozoic granitoid at Nd [180 Ma] of -2.8. These data suggest mid-Proterozoic separation of the crust in central northern New England. Moreover, the bulk of the Mesozoic granites cannot be explained as crustal melts but must have large mantle components. The ranges of Nd and Sr isotopes are attributed to incorporation of crust by magmas derived from midly depleted mantle sources. Crustal input may reflect either magma mixing of crustal and mantle melts or crustal assimilation which is the favored interpretation. The results indicate production of anorogenic granites from mantle-derived mafic magmas.  相似文献   

9.
Genesis of high Mg# andesites and the continental crust   总被引:38,自引:2,他引:36  
The continental crust has an andesitic composition with high Mg/(Mg+Fe) and Ni contents which may be too high to have formed by differentiation of basaltic magmas. Instead, mantle-derived, high Mg# andesites (HMA) may form a substantial component of the crust. HMA may be produced by partial melting of previously depleted, subsequently metasomatised mantle peridotite. However, they are more likely produced by reaction between ascending melts and mantle peridotite. HMA are less common than basalts among lavas in modern island arcs, but may have been more common in the past, may be produced in specific environments (such as ridge subduction), may be more common among plutonic rocks in the lower and middle crust than among lavas at the surface, and may be selectively preserved during later erosion and subduction processes.  相似文献   

10.
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   

11.
Based upon a compilation and analysis of O-isotope data for Neogene volcanic rocks worldwide, the 18O variation for 743 basalts (historic lavas, submarine glasses, and lavas with <0.75 wt% H2O) is +2.9 to +11.4. Mid-ocean-ridge basalt (MORB) has a uniform O-isotope composition with 180=+5.7±0.2. Basalts erupted in different tectonic settings have mean 18O/16O ratios that are both lower and higher than MORB, with continental basalts enriched in 18O by ca. 1 over oceanic basalts. The 18O range for the subset of 88 basalts with Mg# [100·Mg(Mg+Fe2+)] 75–68, considered to be unmodified primary mantle partial melts, is +3.6 to +8.7. These features are a clear indication that: (1) the Earth's upper mantle is heterogeneous with respect to its O-isotope composition; (2) that both low-18O and high-18O reservoirs have contributed to basalt petrogenesis. Large-ion lithophile element-enriched basalts associated with subduction at convergent plate margins are slightly enriched in 18O, a characteristic that is considered to be an intrinsic feature of the subduction process. Intraplate oceanic and continental basalts have highly variable 18O/16O ratios, with individual localities displaying 18O ranges in excess of 1.5 to 2. Systematic co-variations between O-, Sr-, Nd-, and Pb-isotope ratios reflect the same principal intramantle end-member isotopic components (DMM, HIMU, EM-I, EM-II) deduced from radiogenic isotope considerations and, therefore, imply that a common process is responsible for the origin of upper mantle stable and radiogenic isotope heterogeneity, namely the recycling of lithospheric material into the mantle.  相似文献   

12.
Explosive eruptions of this large Quaternary rhyolitic volcano have produced voluminous pumice fall deposits and ignimbrites. A stratigraphie study reveals more than 30 fall deposits, totalling more than 90 km3, which have come from many different vents. Some are of plinian type, and one is among the largest known in the world. The main ignimbrite (Rio Caliente) is of intra-plinian type. In all, 140 km3 of rhyolitic material were erupted during the past 105 years, of which 50 km5 are dispersed well outside the volcano. The dense rock equivalent volume is 60 km3, of which fall deposits, ignimbrites and lava bodies comprise 45 %, 25 % and 30 % respectively. The average output rate of 0.06 km3 per century is nearly an order of magnitude less than for the most productive rhyolitic volcanoes known. A circular area 10 km across in the centre of La Primavera contains updomed lacustrine ashes and associated sediments, including a remarkable giant pumice bed, which probably accumulated in a caldera lake. La Primavera has no record of historical eruptions, and hot springs are the only signs of present activity, but the updoming is thought to be due to the uprise of a new acid pluton beneath the volcano and future eruptions are probable.
Zusammenfassung Explosionsartige Eruptionen des gro\en quartÄren Rhyolith-Vulkans La Primavera haben mÄchtige Bimstuffe und Ignimbrite aufgehÄuft. Eine stratigraphische Untersuchung hat über 30 Aschelagen erkennen lassen, die aus verschiedenen Schloten stammen und insgesamt mehr als 90 km3 an Volumen ausmachen. Einige davon gehören zum plimanischen Typ, von denen eine sogar die grö\te bisher bekannte Lage der Erde ist. Der Haupt-Ignimbrit (Rio Caliente) gehört zum intraplimanischen Typ. Insgesamt wurden in den letzten 100 000 Jahren 140 km3 rhyolithisches Material ausgeworfen, von denen 50 km3 deutlich au\erhalb des eigentlichen Vulkans liegen. Das Äquivalentvolumen des dichten Gesteins betrÄgt 60 km3, von dem 45 % auf Tuffe, 25 % auf Ignimbrite und 30 % auf Lavakörper entfallen. Die durchschnittliche Auswurfrate von 0,06 km3 pro Jahrhundert liegt fast eine Grö\enordnung unter den meisten bekannten aktiven Rhyolith-Vulkanen. Ein kreisrundes Gebiet von 10 km Durchmesser im Zentrum des La Primavera zeigt aufgewölbte lakustrine Aschen und damit assoziierte Sedimente, darunter eine bemerkenswerte riesige Bimslage, die wahrscheinlich in einem Caldera-See abgelagert wurde. Der Vulkan La Primavera ist in historischer Zeit nicht ausgebrochen und hei\e Quellen sind die einzigen Anzeichen heutiger AktivitÄt, aber die Aufwölbung wird als Hinweis auf das Hochdringen eines neuen sauren Plutons unter dem Vulkan angesehen, so da\ zukünftige Eruptionen wahrscheinlich sind.
Résumé Des éruptions explosives de ce grand volcan rhyolitique quaternaire ont produit de volumineux dépÔts de ponces et d'ignimbrites. Une étude stratigraphique fait apparaÎtre plus de 30 dépÔts totalisant plus de 90 km3 provenant de nombreuses bouches volcaniques différentes. Certaines sont du type plinien, dont l'une est parmi les plus grandes connues au monde. L'ignimbrite principale (Rio Caliente) est du type intraplinien. En tout 140 km3 de matériaux rhyolitiques ont été rejetés au cours des 105 dernières années, dont 50 km3 ont été dispersés bien au delà du volcan. Le volume de roche compact équivalent est de 60 km3, parmi lequel les tuffs, les ignimbrites et les laves occupent respectivement 45%, 25% et 30%. L'émission moyenne, de 0,06 km3 par siècle, est d'un ordre de grandeur moindre que pour la plupart des volcans rhyolitiques les plus productifs actuellement connus. Une région circulaire de 10 km de diamètre dans le centre de La Primavera contient des domes de cendres lacustres et autres sédiments associés, et parmi eux une couche géante de ponce remarquable, qui s'est probablement accumulée dans un lac-caldère. On ne connaÎt pas d'éruptions historiques de la Primavera, et seules des sources chaudes témoignent d'une activité actuelle; toutefois on pense que l'allure en dome est due à la poussée d'un nouveau pluton acide sous le volcan, et que des éruptions sont probables dans le futur.
- . 30 , ; 90 3. , . - - - . 3 100 000 140 3 , 50 3 . 60 , 45% , 25% 30% . 0,06 ; , . 10 - , , , . - , , , , .
  相似文献   

13.
The alkaline rocks around Sivamalai are represented by syenites, nepheline syenites and basic alkaline rocks. The syenites are comprised of olivine-pyroxene, pyroxene, hornblende and biotite syenites and syenodiorites, pegmatite phases and quartz syenite. Nepheline syenites include pyroxene, hornblende and biotite bearing varieties. Syenites with pockets of garnet, magnetite or corundum occur in some places between the nepheline syenites and the country rocks represented dominantly by granitic gneisses. The basic alkaline rocks are represented by barkevikite melteigite and they occur as xenoliths amidst the nepheline syenites. The field mineralogical and petrochemical characteristics indicate the igneous nature of these rocks. The syenites and nepheline syenites are inferred to be evolved from pyroxene syenodiorite and barkevikite melteigite respectively. The irregular distribution of garnet and corundum is attributed to the metasomatism of the country rocks by the alkaline magma.
Zusammenfassung Die alkalischen Gesteine um Sivamalai umfassen Syenite, Nephelinsyenite und basische alkalische Gesteine. Die Syenite sind aus Olivin-Pyroxen, Pyroxen, Hornblende und der Biotitsyenit, Syenodiorit, Pegmatitphasen und Quarzsyenit zusammengesetzt. Die Nephelinsyenite schließen Varietäten mit Pyroxen, Hornblende und die Biotite ein. Syenite mit Granatlinsen, Magnetit oder Korund schalten sich an einigen, Stellen zwischen Nephelinsyenite und die weiter verbreiteten granitischen Gneise. Die basischen Alkaligesteine werden durch barkeviktischen Melteigit vertreten und finden sich als Xenolithe im Nephelinsyenit. Der mineralogische und petrochemische Feldbefund läßt auf eruptiven Charakter dieser Gesteine schließen. Es wird angenommen, daß die Syenite und Nephelinsyenite sich aus Pyroxensyenodiorit und Barkevikitmelteigit entwickelt haben. Die ungleichförmige Verteilung von Granat und Korund wird auf die Metasomatose der umgebenden Gesteine durch alkalisches Magma zurückgeführt.
Résumé Les roches alcalins autor de Sivamalai sont représentées par des syénites, des syénites éléolitiques et de roches alcalines basiques. Les syénites comprennent des syénites à péridot, pyroxene, hornblende et biotite, et des syénodiorites, des phases pegmatitiques et des syénites quartziféres. Les syénites éléolitiques comprennent des variétés à pyroxene, hornblende et biotite. Des syénites avec poches à grenat, magnétite ou corindon se rencontrent en quelques endroits entre les syénites éléolitiques et les roches encaissantes représentées principalement par gneiss granititiques. Les roches alcalines basiques sont représentées par des melteigites barkévictiques et se rencontrent en enclaves dans les syénites à néphéline. Les caractéristiques sur le terrain, minérologiques et pétrochimiques, indiquent le caractère igné de ces roches. Les syénites et les syénites éléolitiques sont considérées comme dérivant respectivement de syénodiorites pyroxéniques et de melteigites barkévictiques. La répartition irregulière du grenat et du corindon est attribuée à la métasomatose des roches encaissantes sous l'influence du magma alcalin.
Sivamulai , - . -, , - , -, -. - , . - - , . -. . , - - . .
  相似文献   

14.
The Ascutney Mountain complex of eastern Vermont, USA, is a composite epizonal pluton of genetically related gabbro to granite intrusives. Nd isotopic data are reported for mafic rocks, granites, and nearby country rock. The parental mafic magma producing the complex 122 m.y. ago had 87Sr/86Sr=0.7039, 143Nd/144Nd=0.512678 ( Nd=+3.8) and 18O=6.1, indicating a mantle source with time-integrated lithophile element depletion. Uniform initial radiogenic isotope ratios for granites, which are undistinguishable from those for the most primitive gabbro, suggest that the granite magma evolved from the mafic magma without crustal contamination and that the increase in 18O, to about 7.8, is the result of fractional crystallization. Mafic rocks show a large range in initial 143Nd/144Nd ratio, from about 0.51267 to 0.51236 ( Nd= +3.7 to –2.5), which is correlated with elevated 87Sr/86Sr ratios and 18O. These data substantiate the production of mafic lithologies by fractional crystallization of the parental magma accompanied by assimilation of up to about 50% crust. The local country rocks include gneiss and schist and assimilation involved representatives of both rock types. The isotopic and chemical relationships preclude derivation from a single batch of magma undergoing contamination and indicate that a large magma body at depth evolved largely by fractionation with batches of melt issued from this chamber being variably contaminated at higher levels or at the level of emplacement.The Precambrian gneisses of the Chester dome and overlying lower Paleozoic schists have essentially identical Nd isotope systematics which suggest a crustal formation age of about 1.6. b.y. The parental sediments for the schists were apparently derived from a protolith similar to the gneissic basement without appreciable Sm/Nd fractionation.  相似文献   

15.
Auriferous skarns are associated with post- and late-kinematic Hercynian granites that intruded into Cambro-Ordovician to Devonian sediments of the central Pyrenees. We determined the age of the Andorra granite and the associated skarn at 305 ± 3 Ma by U-Pb dating titanite from the endo-skarn. The sulfur isotopic composition from sulfides in the skarn (Cardellach et al. 1992) shows a significant variation with isotopically light sulfur (34S +3) in the barren skarns and heavy sulfur (34S +11) in the gold-bearing skarns. Outwards, it increasingly resembles sulfur from arsenopyrite disseminations in the Cambro-Ordovician sediments. The lead isotopic composition from sulfides of the skarns is very homogeneous (206Pb/204Pb = 18.410, 207Pb/204Pb = 15.699, 208Pb/204Pb = 38.574) in contrast to the one in gold-bearing arsenopyrite veins and in arsenopyrite disseminations in the sediments (e.g. 206Pb/204Pb varies from 18.54 to 30.36). Combined, sulfur and lead isotope data indicate that the lead in the skarn is dominantly derived from the granite, whereas the sulfur is derived at variable portions from both the granite and the sediments.  相似文献   

16.
The northeastern sector of the Spanish Central System hosts important Stephanian-Permian silver-base metal epithermal mineralizations defining the so-called Hiendelaencina District. The overall geotectonic evolution of this region indicates a major late Variscan extensional period involving the unroofing of dome-shaped metamorphic core complexes, which ultimately led to the radial brittle disruption of these bodies allowing the ascent of andesitic magmas and high-level hydrothermal activity. The deposits are hosted by high-grade metaphorphic rocks belonging to these complexes. Mineralogical and fluid inclusion studies reveal that the mineralizations were formed during two to four hydrothermal stages. These are the result of complex interactions between fluids of contrasted temperatures and salinities. Data on sulphur isotopes suggest that two sources of sulphur existed: magmatic (andesitic derived, with 34S + 6) and metasediment-derived (with initial 34S probably + 25).  相似文献   

17.
The Bitterroot mylonite is a ductile-deformed amphibolitefacies mylonite (A-mylonite), abruptly capped by ductile- to brittle-deformed greenschist-facies mylonite (G-mylonite). The movement picture of the A-mylonite from its lineation and S-C-surfaces is strongly focused; the average orientation for the G-mylonite is similar but much more diffuse.Regional metamorphism, and intrusion of quartz diorite orthogneiss, granodiorite, and granite of the Idaho-Bitterroot batholith between 105 and less than 60 m.y. ago was followed by regional extension, formation of the A-mylonite, and rapid drop in temperature from about 700 °C to about 280 °C, at a time inferred to be about 57 to 53 m.y. ago. Pressure-relief melting of water-undersaturated rocks at deeper crustal levels, in response to the rapid decrease in pressure, may have produced the nearly dry magmas emplaced as very shallow plutons or erupted as the Challis rhyolitic volcanics 52 or 53 m.y. ago.The greenschist-facies mylonite/chloritic breccia formed during further cooling to about 100 °C, during listric normal faulting on the eastern flank of the Bitterroot dome about 40 m.y. ago.
Zusammenfassung Der Bitterroot-Mylonit ist ein duktil deformierter amphibolitfazieller Mylonit (A-Mylonit), der von einem duktil bis spröd deformierten grünschieferfaziellen Mylonit (G-Mylonit) scharf getrennt wird. Das Bewegungsbild des A-Mylonites ist anhand seiner Lineationen und seiner S-C-Gefüge stark ausgerichtet; die Durchschnittsorientierung für die G-Mylonite ist ähnlich, streut aber breiter. Der Regionalmetamorphose, den Intrusionen von Quarzdiorit, Orthogneis, Granodiorit und dem Granitbatholithen von Idaho-Bitterroot zwischen 105 und mindestens 60 Ma folgte eine regionale Dehnungsphase, dann die Bildung der A-Mylonite, danach ein rascher Temperaturabfall von ungefähr 700 °C auf ca. 280 °C, wahrscheinlich im Zeitraum vor 57 bis 53 Ma. Druckabhängiges Schmelzen wasseruntersättigter Gesteine in tieferen Krustenniveaus könnte als Reaktion auf den rapiden Druckabfall zur Bildung der nahezu trockenen Magmen geführt haben, die dann vor ca. 52 oder 53 Ma als sehr flachliegende Plutone intrudierten oder wie der Challis-Rhyolith eruptiert wurden.Der grünschieferfazielle Mylonit und die Chloritbrekzien bildeten sich während der weiteren Abkühlung bis auf ca. 100 °C mit der Entwicklung von listrisch geformten Abschiebungen auf der Ostflanke des Bitterroot-Domes vor ca. 40 Ma.
Résumé L'ensemble mylonitique de Bitterroot comporte une mylonite engendrée par déformation ductile dans le facies des amphibolites (mylonite A), en contact brusque avec une mylonite, ductile à cassante, appartenant au facies des schistes verts (mylonite G). L'image cinématique de la mylonite A est définie de manière très précise par sa linéation et la disposition des plans s et c; l'image de la mylonite G est semblabe, mais plus diffuse.Le métamorphisme régional et l'intrusion de méta-diorite quarzique, de granodiorite et de granite formant le batholite de l'Idaho-Bitterroot, entre 105 Ma et moins de 60 Ma, ont été suivis d'une extension régionale accompagnée de la formation de la mylonite A et d'une chute rapide de la température depuis 700 °C jusqu' à ±280 °C, probablement entre 57 et 53 Ma. La fusion de roches sous-saturées en eau, provoquée dans des niveaux crustaux plus profonds par la baisse rapide de la pression peut être à l'origine des magmas presque secs responsables de la mise en place de plutons peu profonds et d'éruptions comme celle des volcanites rhyolitiques de Challis il y a 52 ou 53 Ma.La mylonite de facies schistes verts et la brèche chloritique se sont formées au cours du refroidissement ultérieur, jusqu'à ±100 °C, à l'occasion de la production de failles normales listriques sur le flanc est du dôme de Bitterroot, il y a environ 40 Ma.
, Bitterroot (-), (G-), . - , Bitterroot, ; , G- , . , -, , Idaho-Bitterroot 105 60 : , — -, — 700 ° 280 °, , , 57 53 . , , , , 52–53 , , Challis. 100 °, Bitterroot 40 .
  相似文献   

18.
The volcanic stratigraphy and petrogenesis of the Oman ophiolite complex   总被引:12,自引:0,他引:12  
The volcanic stratigraphy and trace element geochemistry of the Oman ophiolite complex indicate a multistage magmatic origin comprising: (1) magmatism due to sea-floor spreading in a marginal basin; (2) magmatism associated with discrete submarine volcanic centres or seamounts; (3) magmatism associated with crustal uplift and rifting; and (4) magmatism associated with continent-arc collision.Trace element petrogenetic modelling is used to investigate the nature of the mantle source region and the partial melting and fractional crystallization history for each magmatic event. The petrogenetic pathway for the sea-floor spreading lavas requires a high degree of melting of a mantle that was depleted in incompatible elements prior to subduction but subsequently selectively enriched in certain elements (mostly LIL elements and H2O) from an underlying subduction zone; it also requires magma mixing in an open system magma chamber prior to eruption. The seamount lavas were probably derived by a similar degree of partial melting of a similar source, but fractional crystallization was restricted to smaller high-level magma chambers. The rifting lavas were derived from a mantle source that was more depleted than the seamount lavas prior to subduction but which was later modified by a larger subduction zone component. The syn-collision lavas were however derived from an enriched mantle source, which probably underlay the passive continental margin rather than the marginal basin complex. Results such as these may provide considerable insight into the petrogenetic changes accompanying the transitions from spreading to arc volcanism in a supra-subduction zone setting.  相似文献   

19.
The Kern Mountains plutonic complex is composed of multiple intrusions referred as the Cove, Tungstonia and Hoodoo Canyon plutons, whose emplacement was structurally controlled. The plutons are members of the calc-alcaline granite series, leucogranite type that are relatively alkali rich. The complex is of epizone (4–10 km) and was emplaced during Jurassic time into the carbonates and quartzite of Paleozoic age. Trace and major element data indicate that the complex was derived from the partial melting of rocks similar to Canadian Shield rocks. Analysis of variance of chemical data suggets that hydrothermal solutions carried K2O, Na2O and SiO2 and raised the levels of original oxides in the plutons. Hydrothermal activity is evidenced by the occurrence of second generation muscovite, potassium feldspar and quartz in the complex and tungsten and sulphide mineralization in the area.
Zusammenfassung Der plutonische Komplex des Kerngebirges besteht aus mehrfachen Instrusionen, genannt Cove-, Tungstonia- und Hoodoo Canyon-Pluton, deren Platznahme tektonisch kontrolliert wurde. Die plutonischen Gesteine gehören zu den Kalkalkaligraniten; sie sind leucogranitisch und damit ziemlich alkalireich. Der Komplex ist epizonal (4–10 km), er drang während des Jura in die Karbonate und Quarzite des Paläozoikums ein. Spuren- und Hauptelementmeßwerte zeigen an, daß der Komplex von aufgeschmolzenen Gesteinen abgeleitet werden kann, die den Gesteinen des Kanadischen Schildes ähneln. Die Analyse der Variation von chemischen Meßwerten deutet an, daß hydrothermale Lösungen K2O, Na2O und SiO2 enthielten, die das Niveau der ursprünglichen Oxide in den plutonischen Gesteinen erhöhten. Die hydrothermale Tätigkeit wird durch das Vorhandensein von Muskowit, Kaliunifeldspat und Quartz der zweiten Generation innerhalb des Komplexes und durch Wolfram- und Sulfidmineralisation in der Umgebung bewiesen.
Résumé L'ensemble plutonique des montagnes de Kern, consiste en de nombreuses intrusions dénommées plutons du »Cove«, de »Tungstonia«, et du »Hoodoo Canyon« dont la mise en place a été tectoniquement controlée. Ces plutons font partie de la série granitique calco-alkaline; ce sont des leucogranites relativement riches en alcali. L'ensemble est épizonal (4–10 km), et s'est mis en place au cours du Jurassique dans des Calcaires et quartzites d'âge paléozoique. Les données analytiques relatives aux élements majeurs et en trace indiquent que cet ensemble peut provenir de la fusion partielle de roches similaires à celles du Bouclier Canadien.L'analyse de la variation des données chimiques suggère aussi que l'enrichissement de ces plutons en K2O, Na2O, et SiO2 s'est fait à partir de solutions minéralisantes hydrothermales, comme en témoignent non seulement la présence d'une deuxième génération de muscovite, de feldspath potassique et de quartz, mais aussi par la mineralisation en tungstène et en minerais sulfurés à leur voisinage.
, Cove, Tungstonia Hoodoo Canyon, . - ; , , . (4–10 ); . - , , . , K2O, Na2O SiO2, . , .
  相似文献   

20.
Zusammenfassung In den Jahren 1969 bis 1971 wurden in der Morondava-Küstenebene im Westen Madagaskars umfangreiche hydrogeologische Untersuchungen durchgeführt, in deren Zusammenhang mit Hilfe von geoelektrischen Sondierungen der Aufbau der oberen 150 m des quartären bis neogenen Untergrundes der Ebene geklärt werden konnte. Durch die Interpretation der geoelektrischen Sondierprofile und deren Anordnung in einer Profilkarte war eine Korrelation von Schichtkomplexen hohen Widerstandes möglich. Die Untersuchung ergab, da\ der Untergrund der Küstenebene ein Delta darstellt, das von zwei Flu\systemen geschüttet wurde. Die Mündungen der heutigen Flüsse Morondava und Andranomena sind gegenüber den alten Flu\systemen nach Süden verschoben.
In 1969 to 1971 comprehensive hydro-geological investigations were carried out in the Morondava Plains in western Madagaskar. In the scope of these investigations, the structure of the upper 150 m of the quaternary and neogene deposits in the coastal plains were determined by means of geo-electrical soundings. The interpretation of the soundings by establishing a profile map, allowed for a correlation of the sequences with high electric resistivity. The investigation showed that the underground of the coastal plains represents a delta, deposited by two rivers. The mouths of the actual Morondava and Andranomena rivers are shifted towards the south in relation to the ancient river systems.
Résumé D'importantes investigations hydro-géologiques ont été effectuées de 1969 à 1971 dans la plaine de Morondava à l'ouest de Madagascar, grâce auxquelles, en procédant également à des sondages géo-électriques, il a été possible de déterminer la structure des 150 m supérieurs du sous-sol quaternaire à néogène.Par l'interprétation des sondages géo-électriques et leur transposition sur une carte des profils, il a été possible d'obtenir une corrélation des couches à haute resistivité. Des recherches ont montré que le sous-sol de la plaine cÔtière représente un delta, remblayé par deux systèmes fluviaux. L'embouchure des fleuves actuels Morondava et Andranomena est déplacée vers le sud par rapport aux anciens systèmes fluviaux.
1969 1971 . . 150 , . , . , , . , .

Vortrag, gehalten am 28. Februar 1974 in Bochum anlä\lich der 64. Jahrestagung der Geologischen Vereinigung.  相似文献   

设为首页 | 免责声明 | 关于勤云 | 加入收藏

Copyright©北京勤云科技发展有限公司  京ICP备09084417号