Geological-petrographic properties of Late Miocene granitoids from the Caucasian Mineral Waters region and their relation with the superplume

Doklady Earth Sciences -     

Isotopic (Sr,Nd, O) systematics of the high Sr-Ba Late Miocene granitoid intrusions from the Caucasian Mineral Waters region

This paper is dedicated to the interpretation of isotope-geochemical data on high Sr-Ba granitoids exemplified by their typical representatives—Late Miocene laccoliths of the Caucasian Mineral Waters (CMW). These massifs are made up of amphibole granites, granosyenites, syenites, and leucogranites, which show particular behavior of Sr, Nd, and O isotope systems. The syenites and granosyenites are characterized by δ¹⁸O variations from 8 to 10‰. As compared to them, the amphibole granites have lowered (up to 7‰), while leucogranites, elevated (up to 12.5–13.7‰) oxygen isotope compositions. The (⁸⁷Sr/⁸⁶Sr)_8.3 ratio in the granitoids accounts for 0.7083–0.7086, whereas σ_Nd(T) varies from −4.2 to −2.1.     

The 40Ar/36Ar Isotope Ratio in Spontaneous Gases of Mineral Waters in the Caucasian Region

Regularities in the distribution of ⁴⁰Ar/³⁶Ar values in spontaneous gases were examined for the Caucasian region. It was revealed that the maximal values of this parameter are characteristic for methane water seepages located along the periphery of this mountain structure (Dagestan Wedge and southern and northwestern slopes of the Greater Caucasus). The excess ⁴⁰Ar here is probably genetically related to active tectonic processes (nappes, high seismicity, stresses, and others) rather than mantle source. By contrast, the carbon dioxide of recent volcanic areas is characterized by nearly atmospheric (296) and lower (up to 285) ⁴⁰Ar/³⁶Ar values. In such springs in the Elbrus region, an inverse correlation was revealed between the ⁴⁰Ar/³⁶Ar ratio in gases and concentrations of geothermometer elements (Li, K, Rb, and Cs) in water. This suggests that the Ar isotopic signature is governed by thermal conditions of the gas–water fluid circulation. The contribution of mantle gases with high ⁴⁰Ar/³⁶Ar values turns out to be undetectable against the background of these processes.     

Sulfur isotopic composition of the magnetite-series and ilmenite-series granitoids in Japan

Sulfur isotopic composition has been measured on 30 granitoids and 11 gabbroids from the Cretaceous and Tertiary granitic terranes of Japan. The two series of granitoids, the magnetite-series and ilmenite-series, defined by Ishihara (1977), show two specific isotope trends. The magnetite-series granioids all have positive (su34)S (CDT) values from +1 to +9, while the ilmenite-series rocks are dominated by negative values between –11 and –1. The trend in the ilmenite-series is consistent with the thesis that the magma has been influenced by light biogenic sulfur from the continental crust. The inferred large scale magma-crust interaction in the ilmenite-series granitoids indicates that the emplacement of this series of magma has been governed by a stoping mechanism.In contrast, the magnetite-series granitoids have little if any evidence for significant magma-crust interaction, indicating that the intrusion of this series of magma may have been more or less of fissure-filling type. Their trend towards positive (su3 4)S values (average +5) argues for the introduction of some heavy sulfur, probably of seawater origin, into the mantle derived sulfur. This is most likely to occur in an arctrench system by the subduction of an oceanic plate which accompanies the sulfate-bearing pelagic sediments.The isotopic data of gabbroids, mostly between –1 and +3, are close to the commonly assumed value for mantle sulfur. Nevertheless, the gabbroids from the magnetite-series granitic terranes tend to have higher (su34)S value than those from the ilmenite-series belts. It is inferred that the factors controlling the isotope characteristics of the granitoid sulfur have also been operative in these grabbroids at least to some extent.     

Oxygen isotopic composition of minerals in the Kenna ureilite

The δ¹⁸O and δ¹⁷O values of olivine from Kenna are 7.6 and 3.0%, respectively, relative to SMOW. These values are typical of ureilites which form a unique group on a δ¹⁷O -δ¹⁸O graph. The ureilites are related to, but not directly derived from, the anhydrous phases of C2 and C3 meteorites. The ¹⁸O/¹⁶O fractionation between pyroxene and olivine is 0.60, indicating a temperature of last equilibration of 1000 ± 100°C.     

O-Sr isotopic variations in Miocene granitoids from the Aegean: evidence for an origin by combined assimilation and fractional crystallization

Sr, O, and D/H isotopic compositions have been analyzed in Miocene metaluminous to slightly peraluminous (I-type) granitoids of the central Aegean. Individual plutonic complexes display significant variations in their ¹⁸O and initial⁸⁷Sr/⁸⁶Sr compositions.D and ¹⁸O compositions of minerals and whole-rocks are mostly in the magmatic range. Some samples from Naxos and Mykonos/Delos show low D and ¹⁸O values characteristic of meteoric-water-hydrothermal interaction, but as a whole the changes in ¹⁸O and Sr isotopic compositions as a result of hydrothermal alteration were slight, even in instances where marked alteration is petrographically observable. Consequently, the bulk-rock variations of ¹⁸O from 8.1 to 12.0 and of⁸⁷Sr/⁸⁶Sr from 0.70438 to 0.71450 may be regarded as primary and indicative of the conditions of their evolution. Heterogeneous isotopic compositions observed in the individual plutons of Serifos, Ikaria, Samos and Kos may be caused by the multiple intrusion of chemically and isotopically distinct magma pulses, with high viscosities and relatively rapid consolidation in most cases preventing complete homogenization. The granitoids of Serifos, Ikaria and Kos display weak correlations between the initial⁸⁷Sr/⁸⁶Sr and ¹⁸O and 1/Sr. The granitoid province shows a positive correlation between⁸⁷Sr/⁸⁶Sr and ¹⁸O and a non-linear relationship between⁸⁷Sr/⁸⁶Sr and 1/Sr, whereby 1/Sr increases more rapidly than the isotopic ratio as the degree of fractionation of the rocks increases. It is argued that assimilation of older continental material by mantle-derived arc magmas with combined fractionation (AFC) is the most plausible model to explain the chemical and isotopic characteristics of the granitoids and the geological situation in which rock-types trend from granodiorites in the (south)west, near the inferred Oligocene-Miocene suture, to granites in the center and monzonites in the (north)east of the province.     

Geochemical and Sr-Nd isotopic evidence for origin and evolution of the Miocene Pangeon granitoids,Southern Rhodope,Greece

The Sr-Nd isotopic ratios of selected post-collisional, calc-alkaline, I-type granitoids from the Pangeon pluton, intruding the lower tectonic unit (LTU) in the Southern Rhodope in the Miocene, support the existence of two types of granitoids (PTG porphyritic tonalite granodiorite and MGG biotite granodiorite to two-mica granite) unrelated by crystal fractionation and likely derived by partial melting of the same source under different P-T conditions. The Sr-Nd isotopic ratios of mafic enclaves in the granitoids as well as metamorphic rocks from the LTU have also been determined. At 22 Ma, the IR_Sr range between 0.706850 and 0.708381, whereas the ε_Nd(22) range from –3.86 to –1.05, with no relationship to granitoid types. The relationships between Sr and Nd isotopes as well as these isotopes and SiO₂ provide evidence of contamination of mafic melts by interaction with crust during magma differentiation. Both partial melting and AFC processes (r = 0.2) may account for compositional variations in the Pangeon magmas. The mafic enclaves display IR_Sr from 0.706189 to 0.707139, and ε_Nd(22) from –2.29 to –1.94, similar to the granitoids, supporting the hypothesis of a common origin. Amphibolites inferred to be subduction-enriched metabasalts under-plated crust during old subduction can represent the source of the Pangeon melts. The T_DM of the Pangeon granitoids is in the range 0.7–1.1 Ga for the inferred extraction age of the LILE-enriched subcontinental lithospheric mantle source. The upper crustal geochemical signatures and the relatively small isotopic composition of the Pangeon granitoids make these rocks similar to the coeval eastern-Mediterranean lamproites emplaced within the same geodynamic setting; this prompts similar melt sources. Lastly, the Pangeon granitoids display geochemical characteristics, isotopic ratios, and T_DM also similar to other Tertiary magmatic rocks from the Southern Rhodope and Biga peninsula, western Anatolia, suggesting a similar tectonic environment and co-magmatic evolution throughout the area.     

Mineral composition of gold-bearing veins and typomorphic features of their minerals in the Kirovskoe deposit (Upper Amur region)

A collection of quartz veinlets with ore mineralization sampled from the dumps of the abandoned pit of the Kirov mine was analyzed with defining the mineral assemblages productive for gold mineralization and determining the composition of the main ore minerals and their typomorphic features, which are used for interpreting the genesis of the mineral associations and the deposit as a whole.     

The New England Batholith: constraints on its derivation from Nd and Sr isotopic studies of granitoids and country rocks

Nd and Sr isotopic compositions are reported for the granitic suites which comprise the late Palaeozoic to earliest Mesozoic New England Batholith of eastern Australia. Some of the granitic suites are typically I-type in their mineralogy, chemistry and isotopic compositions, implying a derivation from igneous (infracrustal) source rocks, whereas other suites have characteristics consistent with a derivation from a protolith which was predominantly sedimentary and relatively felsic (S-types). The I-type granitoids of the Nundle Suite have ?_Nd values (+3.3 to +6.1) that are amongst the most primitive yet documented for a relatively felsic (SiO₂ ~ 65%) plutonic suite and these values imply a derivation from either a depleted upper mantle source or, more probably, a complex source region involving both volcanic-arc rocks and detrital material. Their compositions are distinctly more primitive than those of the New England Super-Suite which constitutes the Permian ‘core’ of the batholith. This extensive Super-Suite (comprising granitoids traditionally designated as I-type) has an overall range in initial Nd and Sr isotopic compositions of ?1.7 to +4.6 and 0.70458 to 0.70624 respectively, although the majority of plutons have initial Nd isotopic compositions which fall into a very narrow range (+1.0 ±1.5 ?units). This limited range is remarkable considering the extreme lithological diversity and range in chemical composition of the analysed samples (SiO₂ 47%–74%) and implies a source region of considerable volume having reasonably uniform isotopic compositions but variation in chemistry. A similarly uniform source isotopically is also indicated for the S-type granitoids of the Carboniferous Hillgrove Suite and Carboniferous-Permian Bundarra Suite with initial ?_Nd values of +0.8 to +2.3 and initial ${}^{87}\text{Sr}{}^{86}\text{Sr}$ compositions of 0.70474 to 0.70577 showing only limited ranges.Five pelites, three ‘felsic’ and four ‘mafic’ greywackes, representing typical country rocks from different stratigraphic levels have initial ?_Nd values (?1.7 to +6.6) and initial ${}^{87}\text{Sr}{}^{86}\text{Sr}$ compositions (0.70378 to 0.70585) which essentially mirror the compositional variation in the granitoids. A chemical, mineralogical and isotopic bimodality in these sediments indicates two very distinctive sources, one felsic (rhyodacitic) the other relatively mafic (andesitic), which were separated spatially and temporally in many but not all areas of early- to mid-Palaeozoic New England. A model is presented in which the S-type granitoids are derived from a predominantly felsic source, i.e. pelites and ‘felsic’ greywackes, whereas some of the granitoids belonging to the New England Super-Suite may have been derived from source rocks consisting of both felsic and mafic sedimentary components.The distinction between many S-type and I-type granitoids in New England is unclear for two principal reasons; (a) because the granitoids and their respective source rocks are relatively young geologically so that their isotopic systems have not evolved to any considerable extent, and (b) because of the intrinsic igneous chemical compositions of any sedimentary component that may be involved in their genesis.     

Rare elements and Nd and Sr isotopic composition in micronodules from the Brazil Basin,Atlantic Ocean

The Sr isotope stratigraphy of the biogenic apatite was used to determine the age of pelagic sediments in the Brazil Basin (Station 1541) that contain ferromanganese micronodules, nodules, and coatings on the weathered volcanic rocks. The age of sediments at horizons 0–5 and 86–90 cm was estimated at 24.1 ± 0.2 Ma and 24.8 ± 0.2 Ma, respectively. The average sedimentation rate in the Late Oligocene was about 13 mm/ka. The hydrogenous Fe–Mn nodule on the sediment surface with the Mn/Fe value of 1.05–1.95 was formed at a rate of 1.2–2.4 mm/Ma, which is 1000 times lower than the growth rate of buried nodule (Mn/Fe 0.4) at depth of 83 cm. Diagenesis provoked changes in the mineral composition of the buried nodule (asbolane-buserite partially replaced by goethite), leading to the loss of a part of Mn, Ni, Li, and Tl but accumulation of trace elements linked with iron oxyhydroxides (Ce, Th, Be, As, and V) were retained. The composition of manganese micronodules at two studied depths in sediments evolved in the course of two stages of ore formation: related to the oxic and suboxic diagenesis. The Sr isotopic composition in manganese micronodules from both horizons do not differ from that of dissolved Sr in the ocean water. The ¹⁴³Nd/¹⁴⁴Nd ratio, which reflects the Nd isotopic composition in the paleocean during the micronodule formation, varies in manganese micronodules from different horizons and is constant in different size fractions.     

U-Pb zircon age and Nd isotopic composition of granitoids,charnockites and supracrustal rocks from Heimefrontfjella,Antarctica

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.

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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.

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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.

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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 ); .

     

白云鄂博矿床稀土矿物稳定同位素特征及其意义

稀土元素是白云鄂博矿床最有特色的矿产。本文在详细讨论了稀土矿物氧、碳同位素制样方法的基础上，对矿床中晚期脉、白云石型矿石、萤石型矿石中的主要稀土矿物进行了系统的氧、碳同位素分析。其中，晚期脉中的氟碳酸盐矿物的碳、氧同位素值较低，具有幔源热液结晶的特点；白云岩型矿石中氟碳铈矿δ１３Ｃ在－１．１‰～－３．４‰，δ１８Ｏ在８．６‰～１２．０‰；独居石δ１８Ｏ在５．７‰～１１．４‰，磷灰石δ１８Ｏ在６．３‰～９．４‰；萤石型矿石中氟碳铈矿δ１３Ｃ在－５．２‰～－５．８‰，δ１８Ｏ在３．６‰～５．５‰；独居石δ１８Ｏ在３．５‰～４．５‰。结合矿床地质特征分析，矿区萤石型矿石和晚期脉的形成可能与深源热液有关；而白云岩中的稀土矿化作用则表现出多源多期次的特点     

Rb,Sr and strontium isotopic composition,K/Ar age and large ion lithophile trace element abundances in rocks and glasses from the Wanapitei Lake impact structure

Shock metamorphosed rocks and shock-produced melt glasses from the Wanapitei Lake impact structure have been examined petrographically and by electron microprobe. Eleven clasts exhibiting varying degrees of shock metamorphism and eight impact-produced glasses have been analyzed for Rb, Sr and Sr isotopic composition. Five clasts and one glass have also been analyzed for large ion lithophile (LIL) trace element abundances including Li, Rb, Sr, and Ba and the REE's.The impact event forming the Wanapitei Lake structure occurred 37 m.y. ago based on K/Ar dating of glass and glassy whole-rock samples. Rb/Sr isotopic dating failed to provide a meaningful whole-rock or internal isochron. The isotopic composition of the glasses can be explained by impact-produced mixing and melting of metasediments. Large ion lithophile trace element abundance patterns confirm the origin of the glasses by total shock melting of metasediments.     

Rubidium,strontium and the isotopic composition of strontium in ultramafic nodule minerals and host basalts

The concentrations of rubidium and strontium and the isotopic composition of strontium have been determined in minerals separated from ultramaflc nodules occurring in late Tertiary and Quaternary basalts of wide geographic distribution. Clinopyroxene, orthopyroxene and olivine from each of three Iherzolite nodules show a relatively wide range of ⁸⁷Sr/⁸⁶Sr disequilibrium and none of the minerals is in isotopic equilibrium with its host basalt. In two cases there is a correlation between ⁸⁷Sr/⁸⁶Sr and ⁸⁷Rb/⁸⁶Sr ratios of the nodule minerals, indicating apparent isochron relationships which may represent relict mantle events. Clinopyroxene and olivine from each of two wehrlite nodules are not in isotopic equilibrium, although the magnitude of the disequilibrium is smaller than that observed in the Iherzolite nodules. None of these ultramafic nodules can be a crystal cumulate from its host basalt, and it is doubtful that any type of genetic relationship exists. The strontium isotopic disequilibrium between nodule minerals seems to be a primary feature inherited from past mantle histories.     

Oxygen and hydrogen isotopic composition of Alpine and pre-Alpine minerals of the Swiss Central Alps

The rocks of the Swiss Central Alps consist of pre-Mesozoic and Mesozoic rocks which were metamorphosed during the Alpine orogeny. Eightysix samples from this area have been analyzed for their isotopic composition (310 mineral phases for their ¹⁸O values and 99 mineral phases for their D values).The mineral phases of pre-Mesozoic and Mesozoic rocks differ significantly in their stable isotope composition. The minerals in pre-Mesozoic rocks display a rather uniform oxygen and hydrogen isotope composition indicative of large-scale homogenization with magmatic fluids. The mineral phases of Mesozoic rocks, on the other hand, show a large variation in their isotopic composition, their ¹⁸O values are heavier, and their D values are isotopically lighter than the pre-Mesozoic phases. These data indicate the lack of a large-scale water supply to the gneissic cores of the Penninic nappes during Alpine metamorphism.Equilibrium conditions, as indicated by concordant oxygen isotope temperatures, are attained in several samples; disequilibrium, however, is more frequently observed, mainly in the central part of the Lepontin area. The pre-Mesozoic rocks recrystallized during Alpine metamorphism. This process was accompanied by partial reequilibration of the oxygen isotopes, and took place in a closed system. In the pre-Mesozoic rocks, the oxygen isotope fractionations, therefore, reflect the temperatures at the time of this recrystallization which, in many cases, is not the maximum temperature of Alpine metamorphism. There is strong evidence that oxygen isotope ratios are frozen during the progressive phase of a metamorphic event.Oxygen isotope fractionations indicate temperatures of Alpine metamorphism ranging from 500 ° C near Andermatt to 700 ° C near the Bergell granite.