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1.
The Ivrea zone represents a tilted cross section through deep continental crust. Sm-Nd isotopic data for peridotites from Baldissero and Balmuccia and for a suite of gabbros from the mafic formation adjacent to the Balmuccia peridotite provide evidence for an event of partial melting 607±19 Ma ago in an extended mantle source with 607 Nd =+0.4±0.3. The peridotites are interpreted as the corresponding melt residue, the lower part of the mafic formation as the complementary melts which underwent further differentiation immediately after extraction. The Finero body represents a complex with layers of phlogopite peridotite, hornblende peridotite, and amphibole-rich gabbro. The isotopic signatures fall into two groups: (1) highly radiogenic Nd and low-radiogenic Sr characterize the phlogopite-free, amphibole-rich rocks, whereas (2) low-radiogenic Nd and highly radiogenic Sr is found in ultramafics affected by phlogopite metasomatism. Phlogopite metasomatism in the Ivrea zone is dated by a Rb-Sr whole rock isochron yielding 293±13 Ma. It was fed by K-rich fluids which were probably derived from metasediments. The high initial 293 Nd value of about +7.5 for phlogopite-free samples indicates a high time-integrated Sm/Nd ratio in the Finero protolith 293 Ma ago. Sm-Nd analyses of metapelites from the paragneiss series yield Proterozoic crustal residence ages of 1.2 to 1.8 Ga. Internal Sm-Nd isochrons for three garnetiferous rocks show that closure of garnet at temperatures around 600° C or even lower occurred about 250 Ma ago.  相似文献   

2.
The Peräpohja schist belt in northern Finland rests unconformably on Archaean granitoids, and marks the early stages of Proterozoic crustal evolution in the Fennoscandian (Baltic) shield. 2440 Ma old layered mafic intrusions predate the supracrustal , and ca. 2200 Ma old sills of the gabbro-wehrlite association intrude the lowest quartzites and volcanics (Runkaus) of the sequence. The Sm-Nd mineral isochron of the Penikat layered intrusion gives an age of 2410±64 Ma. The initial Nd-values of the Penikat intrusion (Nd(2440) = –1.6) and the Runkausvaara sill (Nd(2200) 0) suggest that these mafic magmas were contaminated by older crustal material. The Sm-Nd and Pb isotopic results on the 2.44–2.2 Ga old Runkaus volcanics indicate mobility of Pb, fractionation of Sm/Nd during late greenschist facies metamorphism, and crustal contamination. The Pb-Pb data provide an age of 1972±80 Ma with a high initial 207Pb/204Pb ratio (1 = 8.49), while scattered Sm-Nd data result in an imprecise age of 2330±180 Ma, with an initial Nd-value of about zero. Secondary titanite gives an U-Pb age of ca. 2250 Ma. The Jouttiaapa basalts, in contrast, ascended from the mantle without interaction with older crust. These LREE depleted tholeiites mark a break in continental sedimentation, and yield a Sm-Nd age of 2090±70 Ma. Their initial Nd = + 4.2 ±0.5 implies that the subcontinental early Proterozoic mantle had been depleted in LREE for a long period of time. The first lava flows are strongly depleted in LREE, suggesting that their source was significantly more depleted than the source of mid-ocean ridge basalts today.  相似文献   

3.
Initial Nd isotope ratios are determined for components of 1.9-1.7 Ga age continental crust in the Ketilidian terrain of South Greenland. The Ketilidian has well-documented ages of migmatization/metamorphism (1.80 Ga) and post-tectonic granitoid intrusion (1.76-1.74 Ga) from U-Pb zircon studies. The Nd results show that: (1) metatholeiites with chondritic 147Sm/144Nd have Nd=+4 to +5 at 1.8 Ga; (2) migmatites, paragneisses and an early granitoid have Nd close to zero; (3) post-tectonic norites have Nd +1.5, while spatially associated more-abundant granitoids have Nd=0 to +1. The metatholeiites show that a normal depleted mantle (Nd=+4 to +5) was present beneath this 1.9-1.7 Ga orogenic zone, as is the case in such environments today. However, metatholeiites are an insignificant part of the Ketilidian crust, and the bulk initial ratio of the whole terrain lies close to Nd=0. Rather than invoking depleted and undepleted mantle sources whose products did not mix, we infer the Nd=0 value to be caused by mixing of a component derived from depleted mantle (Nd=+ 4 to +5) with Archean crustal material (Nd=-9 to -13). As there are no proven relics of Archean crust beyond the border zone of the Ketilidian, and the Nd= 0 value appears to be a wellhomogenized feature, we propose that the Archean material was added in the form of sediments transported to the orogenic zone on oceanic crust. The Archean component comprised between 5 and 17% of the Ketilidian, and the most reasonable estimate is 10%. Thus this 1.9-1.7 Ga terrain consisted of 90% new mantle-derived crust.  相似文献   

4.
Initial Nd isotopic ratios are reported for 23 samples representing magmatic crustal components in the Svecokarelian terrain of South Finland. U-Pb zircon ages are determined for all geologic units, involving 21 separate upper concordia intercept ages based on more than 100 UP-b analyses. The ages range for all the rocks from 1.90 Ga for primitve plutonic rocks to 1.79 Ga for post-tectonic intrusions. The well-known gabbro-diorite-tonalite-trondhjemite association of the Kalanti district appears to consist of components with different ages: trondhjemites are probably 1.90 Ga or older, diorites/tonalites belong to the main Svecokarelian plutonic eposide at 1.89-1.87 Ga, and at least some gabbro has a post-tectonic age of 1.80 Ga. Nd (T) values range between +2 to +3 for meta-andesites, large gabbros and primitive granitoids to –0.5 for more evolved granitoids. A magma source with Nd of at least +2 to +3 was available during 1.90 to 1.87 Ga, but evolved granitoids have Nd close to zero. The preferred interpretation is that depleted mantle with Nd=+4 to +5 was present beneath the Svecokarelian crust forming during 1.9-1.8 Ga, and that all rocks have been affected more or less by addition of an Archean crustal component with Nd=–9 to –13. The primitive rocks with Nd=+2 to + 3 were only slightly affected, while granitoids with Nd close to zero include a 10% Archean component. The widespread nature of the Archean addition and the distance of up to 500 km to actual exposed Archean crust make it most realistic that the Archean component was added to the form of sediments delivered by subducting Proterozoic ocean crust. The plutonic rocks of the Finnish Svecokarelian crust in areas away from Archean cratons consist of 90% newly mantle-derived material.  相似文献   

5.
Single zircons from two orthogneiss complexes, the Grey Gneiss and Red Gneiss, the lowermost tectonic units in the Erzgebirge, were dated. The grey Freiberg Gneiss is of igneous origin and has a 207Pb/206Pb emplacement age of 550±7 Ma. A quartz monzonite from Lauenstein contains idiomorphic zircons with a mean 207Pb/206Pb age of 555±7 Ma as well as xenocrysts ranging in age between 850 and 1910 Ma. Red gneisses from the central Erzgebirge contain complex zircon populations, including numerous xenocrysts up to 2464 Ma in age. The youngest, idiomorphic, zircons in all samples yielded uniform 207Pb/206Pb ages between 550±9 and 554±10 Ma. Nd isotopic data support the interpretation of crustal anatexis for the origin of both units. Nd(t) values for the grey gneisses are –7.5 and –6.0 respectively, (mean crustal residence ages of 1.7–1.8 Ga). The red gneisses have a wider range in Nd(t) values from –7.7 to –2.8 (T DM ages of 1.4–1.8 Ga). The zircon ages document a distinct late Proterozoic phase of granitoid magmatism, similar in age to granitoids in the Lusatian block farther north-east. However, Palaeozoic deformation as well as medium pressure metamorphism ( 8 kbar/600–650° C) are identical in both gneiss units and distinguish these rocks from the Lusatian granitoids. The grey and red gneisses were overthrust by units with abundant high-pressure relicts and a contrasting P-T evolution. Zircon xenocryst and Nd model ages in the range 1000–1700 Ma are similar to those in granitoid rocks of Lusatia and the West-Sudetes, and document a pre-Cadomian basement in parts of east-central Europe that, chronologically, has similarities with the Sveconorwegian domain in the Baltic Shield.  相似文献   

6.
The ca. 2.7–2.5 Ga Slave Province is a granitegreenstone terrane comprising deformed sedimentary and subordinate volcanic belts extensively intruded by granitoid rocks. The Nd isotopic data are reported for 58 samples of supracrustal and granitoid rocks exposed along a 400 km, east-west, transect at 65°N across the structural grain of the province. Initial Nd values reveal distinctly different crustal sources in the eastern compared to the western parts of the province, as expected from tectonic assembly of the province through accretion of juvenile crust to older continental crust. Supracrustal sequences (ca. 2.71–2.65 Ga) from the central and eastern parts of the province have positive Nd(1) values (+0.3 to +3.6), consistent with juvenile sources and formation remote from significantly older crust. Syn to late-deformation (ca. 2.63–2.60 Ga), mantle-derived diorites and related tonalites (type I) from the central and eastern parts of the province have similar initial Nd values (-0.1 to +2.7). In contrast, samples from the westernmost plutons, which intrude exposed pre-3.1 Ga crust, have much lower Nd(1) values (-1.0 to4.6) suggesting contamination of these magmas by older crust. The Nd(1) values of post-deformation granites (s.s.) (type II) also vary systematically across the province: values for granites west of longitude 110°30W range from-0.2 to -5.3; those to the east range from +0.6 to +3.7. These data suggest mixed crustal sources dominated by Mid to Early Archean material ( Nd-2.6 to- 17 at 2.6 Ga) for the western granitoid rocks and juvenile sources for the eastern granites. The Nd isotopic data are consistent with the geology of the province in that exposures of Mid to Early Archean crustal rocks, predating the principal 2.7–2.5 Ga orogenic event are restricted to the western part of the province. The asymmetric pattern defined by the Nd isotopic data indicates the presence of distinct crustal rocks beneath the Slave Province. Similar isotopic variations observed across Phanerozoic collisional orogens have been interpreted to reflect tectonic assembly of crust by accretion of juvenile crustal terranes to an older continental margin. This process may also have been an important mechanism in the cratonization of the Slave Province.  相似文献   

7.
Rocks with boninitic affinities have been recognised in a number of ophiolites, including the Cambrian Heathcote and Mt Wellington Greenstone Belts of Victoria. Boninites and high-Mg andesites from the Heathcote Greenstone Belt show a restricted range of initial Nd values of between +3.3 to +5.8. Extremely refractory boninites from the Mt Wellington Greenstone Belt have Nd ranging from +1.3 to –9. Ti/Zr is positively correlated with Sm/Nd with the Heathcote lavas generally possessing greater depletion of Ti and enrichment of Zr relative to the middle and heavy REE with increasing LREE/HREE. These data are consistent with the generation of boninites by partial melting of refractory peridotite following invasion by LREE- and Zr-enriched, low Nd fluids. Tholeiites overlying the boninites in both greenstone belts have flat REE patterns and Nd+5, lower than that anticipated for lavas derived from depleted MORB source reservoirs in the Cambrian, suggesting that their source was also contaminated by a LREE-enriched, low Nd component similar to that involved in the generation of the Howqua boninites. The added components have characteristics compatible with their derivation from subducted altered oceanic crust and/or from wet subducted sediments. The identification of boninites and other low-Ti lavas in the Victorian greenstone belts is strong evidence for island arc development in southeastern Australia during the Lower Cambrian and provides further support for a subduction-related origin for many ophiolites.  相似文献   

8.
Whole-rock and mineral samples from the Jabal al Wask and Jabal Ess ophiolites, northwestern Saudi Arabia, yield Sm-Nd isochron ages of 743+24 Ma and 782±38 Ma, respectively. These formation ages, which provide maximum limits for possible obduction ages, are in broad but not precise agreement with the previously known geologic history of the Arabian Shield. They indicate that the ophiolitic rocks are roughly coeval with nearby volcanic and plutonic rocks, supporting a back-arc origin for the two ophiolites. We suggest that the Jabal al Wask and Jabal Ess ophiolites were parts of the same northeast-southwest trending ophiolite belt, now offset along the Najd fault system. Initial Nd values range from +6.6 to+ 7.6, indicating derivation from a mantle source that has been LIL-depleted for at least 2 Ga. Reported Nd values from the Arabian Shield that are lower than this suggest the presence of older, reworked continental crust.  相似文献   

9.
The Mariánské Lázn complex (MLC) is located in the Bohemian Massif along the north-western margin of the Teplá-Barrandian microplate and consists of metagabbro, amphibolite and eclogite, with subordinate amounts of serpentinite, felsic gneiss and calcsilicate rocks. The MLC is interpreted as a metaophiolite complex that marks the suture zone between the Saxothuringian rocks to the north-west and the Teplá-Barrandian microplate to the south-east. Sm-Nd geochronology of garnet-omphacite pairs from two eclogite samples yields ages of 377±7, and 367±4 Ma. Samples of eclogite and amphibolite do not define a whole rock Sm-Nd isochron, even though there is a large range in Sm/Nd ratio, implying that the suite of samples may not be cogenetic. Eclogites do not have correlated Nd values and initial 87Sr/86Sr ratios. Five of the eight eclogite samples have high Nd values (+10.2 to +7.1) consistent with derivation from a MORB-like source, but variable 87Sr/86Sr ratios (0.7033 to 0.7059) which probably reflect hydrothermal seawater alteration. Three other eclogite samples have lower Nd values (+ 5.4 to –0.8) and widely variable 87Sr/86Sr ratios (0.7033 to 0.7096). Such low Nd values are inconsistent with derivation from a MORB, source and may reflect a subduction or oceanic island basalt component in their source. The MLC is an important petrotectonic element in the Bohemian Massif, providing evidence for Cambro-Ordovician formation of oceanic crust and interaction with seawater, Late Devonian (Frasnian-Famennian) high- and medium-pressure metamorphism related to closure of a Saxothuringian ocean basin, Early Carboniferous (Viséan) thrusting of the Teplá terrane over Saxothuringian rocks and Late Viséan extension.  相似文献   

10.
Young volcanic rocks from different sections of the Aleutian Islands-Alaska Peninsula Arc have been measured for 87Sr/86Sr, 143Nd/144Nd and some trace elements. We found the 143Nd/144Nd to be highly restricted in range ( Nd=6 to 7) and low as compared to midocean ridge ba-salts (MORB). This indicates that the source of the Aleutian Arc magmas is different from MORB and remarkably isotopically homogeneous with respect to Nd. The range reported here for arc rocks is substantially smaller than found by other workers. However, the Sr isotope ratios vary considerably ( Sr=–24 to –14). Those samples from small volcanic centers north of the main arc (second arc) are characterized by low Sr. Our data in combination with previous studies suggest that there are slight geochemical differences between discrete sections of the arc. The general uniformity of Nd isotope ratios are thought to be the surface expression of an efficient mixing or homogenization process beneath the arc plate, but which still causes a wide dispersion in Sr isotopic composition.To relate the arc rocks to the broader tectonic setting and to identify possible sources of arc magmas, measurements were done on volcanic and sedimentary rocks from the North Pacific/Bering Sea area. Alkali basalts from the back-arc islands St. George, Nunivak and St. Lawrence and alkali-rich tholeiites from the fore-arc have Nd=+4 to +9 and are correlated on the Sr- Nddiagram parallel to the mantle array but shifted to lower Sr. These samples are thought to be isotopically representative of the mantle transported to that region. A tholeiitic basalt from the Kamchatka Basin ocean floor (back-arc), however, yielded typical MORB values ( Nd=10, Sr=–24). Composite sediment samples were made from DSDP cores in the Aleutian Abyssal Plain, Gulf of Alaska and the Alka Basin which represent mixtures of continentally and arc-derived materials. These composites have intermediate Nd isotopic ( Nd= –2 and +2) and high Sr isotopic values ( Sr=+9 and +37). These data show that possible source materials of the Aleutian Arc volcanics are isotopically different from and much more heterogeneous than the arc rocks themselves.On the basis of this study and of literature data, we developed a set of alternative models for volcanic arc magma generation, based on the restricted range in Nd and the wider range in Sr for arc rocks. Different isotopic and trace element characteristics found in different arcs or arc sections are explained by varying mixing proportions or concentrations in source materials. The basic observations require rather strict mixing ratios to obtain constant Nd. The preferred model is one where the melting of subducted oceanic crust is controlled by the amount of trapped sediment with the melting restricted to the upper part of the altered basaltic layer. Homogenization within the upper part of the oceanic crust is brought about by hydrothermal circulation attending dewatering of the slab during subduction and possibly some oxygen exchange of the magmas on ascent.Division Contribution Number 3849 (411)  相似文献   

11.
Sm-Nd systematics for nine whole-rock samples of hornblende norites, pyroxenites and a lamprophyre from various parts of the Cortlandt Complex were analyzed. Six of these samples from the central and eastern parts of the complex give an isochron age of 430±34 (2) Ma with an Nd value of –2.9±0.5, and the other three samples from the western part, including the lamprophyre, define a similar age of 394±33 (2) Ma but with a distinctly different Nd value of –1.4±0.4. The two different initial 143Nd/144Nd ratios corresponding to these -values are interpreted to reflect continental crustal contamination of the lamprophyric parental liquid prior to final emplacement and crystal fractionation to produce the different rock types of the complex. The intrusion age of 430 Ma for the complex clearly post-dates the major metamorphic event of the Taconic orogeny. The Nd-isotopic data also suggest a relationship between the Cortlandt Complex and a belt of lamprophyric dike rocks to the west, known as the Beemerville trend, which cuts across the metamorphic trends of the Taconic (Ratcliffe 1981).  相似文献   

12.
Summary The Salmi batholith is situated on the eastern edge of the EW-trending anorthositerapakivi granite belt of the Fennoscandian shield, at the contact between Proterozoic and Archean crustal domains. The tectonic setting and high K, Rb, Nb, Y, Zr, REE (except Eu), F, Sn, Be, and Li contents of.the Salmi batholith indicate that it represents typical subalkaline A-type and within plate granites. Gabbro-anorthosites of the batholith demonstrate a concordant U-Pb apatite age of 1563 ± 9 (2) Ma and a Sm-Nd internal isochron age of 1552 ± 69 Ma. Zircons from amphibole-biotite granites have an upper concordia intercept U-Pb age of 1543 ± 8 Ma. An older inherited zircon component with elevated Th/U ratio is found in zircons separated from K-feldspar ovoids. Rb-Sr internal errorchron for the granites yields an age of 1455 ± 17 Ma, probably the time of completion of postmagmatic processes within the batholith. The gabbro-anorthosites and granites show similar initial Nd, Sr, and feldspar Pb isotope compositions ( Nd = - 6.5 to - 8.2; 2 = 8.6 to 8.9; 2 = 3.9 to 4.0; ISr = 0.7052 to 0.7057 for the basic rocks, and Nd = -6.2 to -8.9; 2 = 8.1 to 9.2; 2 = 4.0 to 4.4; ISr = 0.7050 to 0.7072 for the granites). Two-stage neodymium TDM model ages for both assemblages range from 2.60 to 2.80 Ga. Old LREE-enriched sources with low time-integrated U/Pb and Rb/Sr and elevated Th/U ratios were involved in the formation of both the gabbroanorthosites and the granites. Bulk contamination with crustal materials cannot explain the data for the basic rocks. Selective incorporation of Pb, Sr, and Nd from Archean lower crust is needed, or else, the gabbro-anorthosites may have been derived from an isotopically anomalous subcontinental mantle source. The ascent of a mantle diapir resulted in anatexis of the lower crust and formation of the parent magma for the rapakivi granites.
Pb-Nd-Sr Isotope, und geochemische Daten: Bedeutung für die Entstehung des 1,54–1,56 Salmi Rapakivi Granit-ANorthosit-Batholithen (Karelia, Rußland)
Zusammenfassung Der Salmi-Batholith ist am östlichen Rand des Ost-West streichenden Anorthosit Rapakivi-Granitgürtels des fennoskandischen Schildes am Kontakt zwischen proterozoischen und archaischen Krustenbereichen gelegen. Die tektonische Position und hohe K, Rb, Nb, Y, Zr, REE (mit Ausnahme von Eu), F, Sn, Be und Li-Gehalte des Salmi-Batholithen weisen darauf hin, daß es sich hier um einen typischen subalkalischen A-Typ und within plate Granit handelt. Gabbro-Anorthosite des Batholithen zeigen ein konkordantes U-Pb Apatit alter von 1563 ± 9 (2) Ma und ein internes Sm-Nd Isochronenalter von 1552 ± 69 Ma. Zirkone aus den Amphibolit-Biotitgraniten haben ein oberes Concordia U-Pb Alter von 1543 ± Ma. Ein ältere, ererbte Zirkonkom ponente mit erhöhtem Th/U Verhältnis kommt in Zirkonen, die von K-Feldspat Ovoi den abgetrennt wurden, vor. Eine interne Rb-Sr Errorchrone für die Granite ergibtein Alter von 1455 ± 7 Ma. Dies repräsentiert wahrscheinlich die Zeit des Abschlusses postmagmatischer Prozesse innerhalb des Batholithen. Die Gabbro-Anorthosite und Granite zeigen ähnliche Nd, Sr und Feldspat Pb Isotopenzusammensetzungen ( Nd = –6.5 to 8.2; 2 = 8.6 to 8.9; K2 = 3.9 to 4.0; ISr = 0.7052 to 0.7057 für die mafischen Gesteine, und Nd = –6.2 to -8.9; 2 = 8.1 to 9.2; K2 = 4.0 to 4.4; ISr = 0.7050 to 0.7072 für die Granite). Zweistufige Neodymium TDM Modellalter für beide Assoziationen liegen zwischen 2.60 und 2.80 Ga. Alte LREE-angereicherte Quellen mit niedrigen, zeitintegrierten U/Pb und Rb/Sr und erhöhten Th/U Verhältnissen waren bei der Bildung der Gabbro-Anorthosite und Granite involviert. Kontamination mit Krus tenmaterial kann die Daten für die basischen Gesteine nicht erklären. Entwederist dazu eine selektive Inkorporation von Pb, Sr und Nd aus der tieferen archaischen Kruste erforderlich oder man muß annehmen, daß die Gabbro-Anorthosite von einer isotopisch anomalen subkontinentalen Mantelquelle stammen. Der Aufstieg eines Mantel-Diapirs führt zu Anatexis der tieferen Kruste und zur Bildung der Ausgangsmagmen für die Rapakivi Granite.
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13.
The reaction stilbite=laumontite+3 quartz+3 H2O was experimentally studied using conventional hydrothermal techniques employing mineral mixtures consisting of reactants and products in 91 and 19 ratios. Equilibrium was demonstrated; the univariant curve passes through about 170° C and 2000 bars, 185°±10° C and 3000 bars, about 185° C and 4000 bars, and 183°±10° C at 5000 bars P fluid. These results combined with published equilibria for analcime, laumontite, wairakite and prehnite permit delineation of the P-T conditions for the zeolite and prehnite-pumpellyite facies metamorphism in the Tanzawa Mountains, Japan.  相似文献   

14.
Rb-Sr isotopic data for anorthosites, charnockites, ferrodioritic to quartz monzonitic plutons, and high-grade gneisses of the Blue Ridge of central Virginia show evidence of post-emplacement metamorphism, but in some cases retain Grenville ages. The Pedlar River Charnockite Suite yields an isochron age of 1021 +/-36 Ma, (initial 87Sr/86Sr ratio of 0.7047 +/-6), which agrees with published U-Pb zircon ages. Five samples of that unit which contain Paleozoic mylonitic fabrics define a regression line of 683 Ma, interpreted as a mixing line with no age significance. Samples of the Roseland Anorthosite Complex show excessive scatter on a Rb-Sr evolution diagram probably due to Paleozoic (475 m.y.) metamorphism. Data from the ferrodioritic to quartz monzonitic plutons of the area yield an age of 1009 +/-26 Ma (inital ratio=0.7058 +/-4), which is in the range of the U-Pb zircon ages of 1000–1100 Ma. The Stage Road Layered Gneiss yields an age of 1147 +/-34 Ma (initial ratio of 0.7047 +/- 5).Sm-Nd data for the Pedlar River Charnockite Suite reflect a pre-Grenville age of 1489 +/-118 Ma ( Nd=+6.7 +/-1.2). Data for the Roseland Anorthosite Complex and the ferrodioritic to quartz monzonitic plutons yield Grenville isochron ages of 1045 +/44 Ma ( Nd=+1.0 +/-0.3) and 1027 +/-101 Ma ( Nd=+1.4 +/-1.0), respectively. Two Roseland Anorthosite samples plot far above the isochron, demonstrating the effects of post-emplacement disturbance of Sm-Nd systematics, while mylonitized Pedlar River Charnockite Suite samples show no evidence of Sm-Nd redistribution.The disparity of the Sm-Nd age and other isotopic ages for the Pedlar River Charnockite Suite probably reflects a Sm-Nd source age, suggesting the presence of an older crust within this portion of the ca. 1 Ga old basement.  相似文献   

15.
Stibnite mineralisation in the antimony province of New England can be divided into Central type ores (veins of stibnite + quartz ± berthierite) and Peripheral type ores of stibnite + quartz + native antimony ± berthierite. The Central stibnites have 34SCDT values of –5±2 (1) which may represent equilibrium precipitation from mantle sulfur at about 200°C. Peripheral stibnites have 34S values between 0 and –25, with a large group at 0±2. They represent precipitation from a limited supply of mantle sulfur and the acquisition of sedimentary sulfur. We consider that the different ore types were produced from distinct ore solutions derived from two immiscible melts. These originated in the deep mantle, were mobilised by tectonic activity and supplied the antimony and most of the sulfur to the ores.  相似文献   

16.
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   

17.
Initial Nd and Sr isotopic ratios have been measured for Cretaceous acidic and related intermediate rocks (24 volcanic and two plutonic rocks) from the Inner Zone of Southwest Japan (IZSWJ) to investigate the genesis of acidic magmas. The initial Nd and Sr isotopic ratios for these rocks show three interesting features: (1) Nd values for acidic rocks (+2 to –9) are negatively correlated with Sr values (+10 to +90) together with those for intermediate rocks ( Nd=+3 to -8; Sr=0 to +65). (2) The Nd values for silica rich rocks (>60% SiO2) correlate with the longitude of the sample locality, decreasing from west to east in a stepwise fashion: Four areas characterized by uniform Nd values are discriminated. (3) Low silica rocks (<60% SiO2) in a certain area have distinctly different Nd values from those of the high silica rocks in the same area.These results as well as those deduced from the additional samples collected, for comparison, from other provinces in Japan suggest that the acidic rocks can be formed neither by fractional crystallization processes from more basic magmas nor by crustal assimilation processes. The isotopic variations of the acidic rocks may reflect regional isotopic heterogeneity in the lower crust, and this heterogeneity may ultimately be attributed to the regional heterogeneity of the uppermost-mantle beneath the Japanese Islands.  相似文献   

18.
138Ce/142Ce isotope ratios in Cenozoic island arc volcanic rocks are reported for the first time, together with isotope ratios of Nd and Sr and abundances of REE, Ba and Sr. The island arc volcanics studies here are boninites from Chichijima, the Bonin Islands, and basalts and andesites from the Solomon Islands. REE patterns of the island arc volcanic rocks from the Solmon Islands and the Bonin Islands are confirmed to have negative Ce anomalies. It is also disclosed that the majority of these island arc volcanic rocks show mainly positive values for both Ce and Nd. It is shown that these Ce and Ce values can hardly be interpreted by simple mixing between MORB and oceanic or continental crustal rocks; the former have positive Nd and negative Ce and the latter have negative Ce and positive or negative Nd. Existence of sources having positive Ce and Nd values is strongly suggested. If the sources are assumed to have been fractionated from CHUR (chondritic uniform reservoir) at the early or middle Precambrian era, the sources from which the volcanics were derived are concluded to have kept concave REE patterns with larger (La/Ce)N and smaller (Nd/Sm)N ratios than chondritic values over a substantial period of time, until the time of Cenozoic magmatism forming island arc volcanic rocks in question. During the periods of the Cenozoic magmatic activities and their related events, Ce anomalies are considered to have been created. From Ce and Nd isotope ratios, however, it is difficult to determine which of the following processes was responsible for the Ce anomaly; the incorporation process of subducted oceanic crust into magma at the mantle or the slab dehydration and metasomatism process. Nevertheless, so far as Ce and Nd isotopic ratios are concerned, incorporation of oceanic sediments did not take place to any clearly detectable degree.  相似文献   

19.
The Closepet batholith in South India is generally considered as a typical crustal granite emplaced 2.5 Ga ago and derived through partial melting of the surrounding Peninsular Gneisses (3.3 to 3.0 Ga). In the field, it appears as a composite batholith made up of at least two groups of intrusions. (a) An early SiO2-poor group (clinopyroxene quartz-monzonite and porphyritic phyritic monzogranite) is located in the central part of the batholith. These rocks display a narrow range in both initial 87Sr/86Sr (0.7017–0.7035) and Nd(–0.9to –4.1). (b) A later SiO2-rich group (equigranular grey and pink granites) is located along the interface between the SiO2-poor group and the Peninsular Gneisses. They progressively grade into migmatised Peninsular Gneisses, thus indicating their anatectic derivation. Their isotopic characteristics vary over a wide range (87Sr/86Sr ratios=0.7028–0.7336 and Nd values from-2.7 to-8.3, at 2.52 Ga). Field and geochronological evidence shows that the two groups are broadly contemporaneous (2.518–2.513 Ga) and mechanically mixed. This observation is supported by the chemical data that display well defined mixing trends in the Sr vs Nd and elemental variation diagrams. The continuous chemical variation of the two magmatic bodies is interpreted in terms of interaction and mixing of two unrelated end-members derived from different source regions (enriched peridotitic mantle and Peninsular Gneisses). It is proposed that the intrusion of mantle-derived magmas into mid-crustal levels occurred along a transcurrent shear zone; these magmas supplied additional heat and fluids that initiated anatexis of the surrounding crust. During this event, large-scale mixing occurred between mantle and crustal melts, thus generating the composite Closepet batholith. The mantle-derived magmatism is clearly associated with granulite facies metamorphism 2.51±0.01 Ga ago. Both are interpreted as resulting from a major crustal accretion event, possibly related to mantle plume activity.  相似文献   

20.
Heimefrontfjella and Mannefallknausane, in Dronning Maud Land, Antarctica, comprise an amphibolite-facies terrain and a granulite terrain, separated by a major mylonite zone. The amphibolite terrain is made up of mafic to felsic metavolcanics and metasediments, intruded by granitoid plutons: the granulite terrain has supracrustal rocks with similar lithologies, intruded by felsic plutonic rocks that crystallized as charnockites.U-Pb zircon ages (conventional and ion microprobe) demonstrate that magmatic activity was confined to a relatively short interval between 1130 and 1045 Ma and was followed in the amphibolite terrain by metamorphism around 1060 Ma. Specific ages are as follows: metarhyolite in the amphibolite terrain, 1093 ± 38 Ma; granitoids in the amphibolite terrain, 1045 ± 9 Ma to 1107 ± 16 Ma, charnockites in the granulite terrain, 1073 ± 8 Ma to 1135 ± 8 Ma, metamorphic zircons in garnet amphibolite and a post-metamorphic pegmatite, both 1060 ± 8 Ma. Older zircons were found only in a metasediment which yielded discordant zircon fractions with207Pb/206Pb ages between 1250 and 1450 Ma, and in a granulite facies metaquartzite, which contained concordant zircons with the following ages: 1104 ± 5 Ma, 1215 ± 15 Ma, 1400 Ma, 1700 Ma, 2000 Ma. The youngest age is interpreted as the age of granulite metamorphism, the older ages as those of detrital zircons.A Sm-Nd mineral isochron age of the garnet amphibolite (960 ± 120 Ma) agrees within error with the U-Pb age of metamorphic zircons (1060 ± 8 Ma). Initial Nd values (T = 1.1 Ga) for 15 samples range from +4 to–4. The highest came from a metabasalt and two granitoids from Milorgfjella, the northern area; the lowest from the granulite-facies metasediment and from a charnockite, both from Vardeklettane, a nunatak in the south. The positive but subdued values preclude generation directly from depleted MORB-type mantle Nd + 6 to + 7 at 1.1 Ga) and indicate generation from a source containing older crustal material.
Zusammenfassung Die Gebiete um Heimefrontfjella und Mannefallknausane in Dronning Maud Land, Antarktis, bestehen aus amphibolith- und granulitfaziellen Grundgebirgskomplexen, die durch eine große Mylonitzone voneinander getrennt sind. Der amphibolithfazielle Komplex besteht aus mafisch bis felsischen Metavulkaniten und Metasedimenten, die von Granitplutonen intrudiert werden. Der Granulitkomplex enthält Suprakrustalgesteine ähnlicher Art, die von Charnockiten intrudiert werden.U-Pb-Alter, die mit der konventionellen Multikorn-Methode und an der Ionen-Mikrosonde an Einzelkörner bestimmt wurden, engen die magmatische Aktivität zwischen 1130 und 1045 Ma ein. Auf diese Periode folgte in dem amphibolithfaziellen Gebiet eine Regionalmetamorphose um 1060 Ma. Die Einzelalter sind wie folgt: in dem amphibolithfaziellen Komplex ergab ein Metarhyolith 1039 ± 38 Ma, während die Granitoide zwischen 1045 ± 9 Ma und 1107 ± 16 Ma variieren. In dem Granulitkomplex wurden die Charnockite auf 1073 ± 8 Ma bis 1135 ± 8 Ma datiert, während metamorphe Zirkone aus einem Granatamphibolith sowie aus einem posttektonischen Pegmatit identische Alter von 1060 ± 8 Ma ergaben. Ältere Komponenten wurden lediglich in einer Metasediment-Probe gefunden, die diskordante Zirkone mit207Pb/206Pb Altern zwischen ca. 1250 und 1450 Ma enthielt, sowie in einem granulitfaziellen Metaquarzit, in dem konkordante Zirkone die folgenden Alter ergaben: 1104 ± 5 Ma, 1215 ± 15 Ma, 1400 Ma, 1700 Ma, 2000 Ma. Das jüngste Zirkonalter aus dem Metaquarzit interpretieren wir als Zeitpunkt der Granulitmetamorphose, während die höheren Alter detritische Komponenten repräsentieren.Eine Sm-Nd Mineralisochrone für einen Granatamphibolith hat ein Alter von 960 ± 120 Ma, das innerhalb der experimentellen Fehler mit einem U-Pb-Alter von 1060 ± 8 Ma für metamorphe Zirkone übereinstimmt. Initiale Nd-Werte (T = l.1 Ga) für 15 Proben variieren zwischen +4 und -4. Die höchsten Werte wurden für einen Metabasalt und zwei Granitoide von Milorgfjella im nördlichen Arbeitsgebiet bestimmt. Die niedrigsten Werte stammen aus dem granulitfaziellen Metaquarzit und von einem Charnockit, beide aus Vardeklettane, einem Nunatak im Süden. Die leicht positiven Werte lassen eine juvenile Bildung der Wirtsgesteine aus einem MORB-ähnlichen Mantel (Nd + 6 bis + 7 um 1.1 Ga) nicht zu und deuten ein Ausgangsmaterial mit Komponenten älterer kontinentaler Kruste an.
Résumé Les régions de Heimefrontfjella et Mannefallknausane situées dans le Dronning Maud Land en Antartique sont formées par deux zones principales à degrés métamorphiques différents: une à faciès amphibolitique et une autre à faciès granulitiques, séparées par une zone mylonitique. Des roches métavolcaniques à composition variant de basique à felsique ainsi que des roches d'origine sédimentaire composent la zone amphibolitique. Elles sont recoupées par des plutons granitiques. La zone granulitique est formée également par des roches d'origine volcanique et sedimentaire qui sont, elles, recoupées par des charnockites.Les mesures d'U-Pb sur zircons (utilisant la méthode conventionnelle et la microsonde ionique) montrent que l'activité magmatique s'est confinée à une période relativement courte entre 1130 Ma et 1045 Ma. Elle a été suivie par un métamorphisme, il y a 1060 Ma, dans la zone amphibolitique. De façon plus détaillée, les âges sont les suivants: dans la zone amphibolitique, rhyolite datée à 1093 ± 38 Ma, granitoïdes datés à 1045 ± 9 Ma et 1107 ± 16 Ma; dans la zone granulitique, charnockites datées entre 1073 ± 8 Ma et 1135 ± 8 Ma, zircons métamorphiques provenant d'une amphibolite à grenat datés à 1060 ± 8 Ma et pegmatite postmétamorphique datée à 1060 ± 8 Ma. Deux roches ont fourni des zircons donnant des âges plus anciens: un sédiment métamorphisé et un metaquartzite. Les âges207Pb/206Pb obtenus pour les fractions discordantes des zircons du metasediment varient entre 1250 et 1450 Ma alors que le metaquartzite contient des zircons concordants avec les âges suivants: 1104±5 Ma, 1215±15Ma, 1400 Ma, 1700 Ma et 2000 Ma. L'âge le plus jeune obtenu pour le métaquartzite est interprété comme représentant l'âge du métamorphisme granulitique alors que les âges plus anciens représentent les âges de zircons détritiques.Une isochrone Sm-Nd sur minéraux a été obtenue sur une amphibolite à grenat. Elle définit un âge de 960 ± 120 Ma qui correspond, aux erreurs près, à l'âge U-Pb des zircons métamorphiques (1060 ± 8 Ma). Les Ndinitiaux (T = 1,l Ga) obtenus pour 15 échantillons varient entre +4 et –4. Les valeurs les plus élevées ont été obtenues pour un basalte et deux granitoïdes de Milorgfjella situés dans la partie nord; les valeur Nd les plus faibles proviennent du métasédiment dans la zone granulitique et d'une charnockite. Ces deux échantillons se situent dans le nunatak Vardeklettane dans le Sud. Les Nd étant positifs mais toutefois plus faibles que la valeur du manteau appauvri à cette période (entre +6 et +7 à 1,1 Ma), une extraction directe du manteau ne peut être retenue et nous suggérons que la région source contenait du matériau crustal plus ancien.
Heimfreontfjella Mannefallknausane Dronning Maud, , , . , . , ., , 1130 1045 Ma. 1060 . : — 1093±38 Ma, 1045±9 Ma 1107±16 Ma. 1073±8 Ma 1135±8 Ma, - 1060±8 Ma. , , 1250 1450 Ma. : 1104±5 Ma, 1215±15 Ma, 1400 Ma, 1700 Ma 2000 Ma. , , , . Sm-Nd, -, 960±120 Ma, , - 1060±8 Ma. Nd (T=1,1 ) 15 + 4 — 4. Milogrfjella . , Vardeklettane . , MORB (Nd + 6 + 7, 1,1 ); .
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