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141.
142.
143.
David C. Gerlach Hans G. AvéLallemant William P. Leeman 《Earth and Planetary Science Letters》1981,53(2):255-265
The Canyon Mountain ophiolite, Oregon, is exceptional in lacking sheeted dikes, basaltic pillow lavas, and sediments that are characteristic of many other ophiolites. Instead, the uppermost portion of the complex consists of a significant volume of plagiogranites, which, in addition to minor basalts, intrude a large section of keratophyres believed to be of volcanic origin. The trend of intrusive rocks and of bedding in the keratophyres is mostly parallel to layering in the underlying gabbroic cumulates and to contacts between units in the remainder of the ophiolite. It is suggested that the plagiogranites, basalts, and keratophyres comprise a sill complex. Both the plagiogranites and the keratophyres are similar, respectively, to low-K2O plutonic and extrusive rocks of island arcs. The mineralogy and penetrative deformation structures of the ultramafic and some of the gabbroic rocks of the ophiolite indicate greater depth of formation, related to magmatism and diapirism above a Benioff zone. Radiometric age dates of plagiogranites confine the minimum age of the complex to the Early Permian. The Canyon Mountain ophiolite may thus be correlative with other fragments of a Lower Permian arc terrane throughout northeastern Oregon which were chaotically mixed during renewed subduction in middle to late Triassic time. 相似文献
144.
Martin Frey Johannes C. Hunziker James R. O'Neil Hans W. Schwander 《Contributions to Mineralogy and Petrology》1976,55(2):147-179
Nine samples from the Monte Rosa Granite have been investigated by microscopic, X-ray, wet chemical, electron microprobe, stable isotope and Rb-Sr and K-Ar methods. Two mineral assemblages have been distinguished by optical methods and dated as Permian and mid-Tertiary by means of Rb-Sr age determinations. The Permian assemblage comprises quartz, orthoclase, oligoclase, biotite, and muscovite whereas the Alpine assemblage comprises quartz, microcline, albite+epidote or oligoclase, biotite, and phengite.
Disequilibrium between the Permian and Alpine mineral assemblages is documented by the following facts: (i) Two texturally distinguishable generations of white K-mica are 2 M muscovite (Si=3.1–3.2) and 2 M or 3 T phengite (Si=3.3–3.4). Five muscovites show Permian Rb-Sr ages and oxygen isotope fractionations indicating temperatures between 520 and 560 ° C; however, K-Ar ages are mixed or rejuvenated. Phengite always shows mid-Tertiary Rb-Sr ages, (ii) Two biotite generations can be recognized, although textural evidence is often ambiguous. Three out of four texturally old biotites show mid-Tertiary Rb-Sr cooling ages while the oxygen isotopic fractionations point to Permian, mixed or Alpine temperatures, (iii) Comparison of radiogenic and stable isotope relations indicates that the radiogenic isotopes in the interlayer positions of the micas were mobilized during Alpine time without recrystallization, that is, without breaking Al-O or Si-O bonds. High Ti contents in young muscovites and biotites also indicate that the octahedral (and tetrahedral) sites remained undisturbed during rejuvenation. (iv) Isotopic reversals in the order of O18 enrichment between K-feldspar and albite exist.
Arguments for equilibrium during Permian time are meagre because of Alpine overprinting effects. Texturally old muscovites show high temperatures and Permian Rb-Sr ages in concordancy with Rb-Sr whole rock ages. For the tectonically least affected samples, excellent concordance between quartz-muscovite and quartz-biotite Permian temperatures implies oxygen isotope equilibrium in Permian time which was undisturbed during Alpine metamorphism.
Arguments for equilibrium during the mid-Tertiary metamorphism are as follows: (i) Mid-Tertiary Rb-Sr mineral isochrons of up to six minerals exist, (ii) Oxygen isotope temperatures of coexisting Alpine phengites and biotites are concordant.The major factor for the adjustment of the Permian assemblages to Alpine conditions was the degree of Alpine tectonic overprinting rather than the maximum temperatures reached during the mid-Tertiary Alpine metamorphism. The lack of exchange with externally introduced fluid phases in the samples least affected by tectonism indicates that the Monte Rosa Granite stewed in its own juices. This seems to be the major cause for the persistence of Permian ages and corresponding temperatures. 相似文献
145.
A method has been developed to control ammonium fugacity, \(f_{{\text{NH}}_{3}}\), at elevated temperatures and pressures. The method uses an internal nitrogen buffer, the assemblage Cr + CrN, in conjunction with a traditional external hydrogen buffer. In this manner, all gas fugacities in the system N-O-H can be calculated.The Cr + CrN buffer has been applied to study equilibria between buddingtonite (ammonium feldspar), ammonium muscovite, sillimanite, and quartz at a constant gas pressure of 2,000 bars. Two of the five relevant reactions were measured experimentally; from these data, it is possible to calculate isothermal sections at 500, 600, and 700° C.Below 600° C, ammonium muscovite is stable even at extremely low levels of \(f_{{\text{NH}}_{3}}\), while buddingtonite requires \(f_{{\text{NH}}_{3}}\;\geqq\;10^4\) bars. Release of NH3 during progressive metamorphism can be achieved by three processes: thermal decomposition, dehydration, and cation exchange. Within the crust, \(f_{{\text{NH}}_{3}}\) predominates over \(f_{{\text{N}}_{2}}\) by several orders of magnitude; but on the surface, nitrogen released as NH3 by metamorphism will be oxidized to N2. Biological materials provide important intermediate storage for nitrogen compounds during the nitrogen cycle. 相似文献
146.
A new family of unconditionally stable one-step methods for the direct integration of the equations of structural dynamics is introduced and is shown to possess improved algorithmic damping properties which can be continuously controlled. The new methods are compared with members of the Newmark family, and the Houbolt and Wilson methods. 相似文献
147.
Hans -Ulrich Schwarz 《International Journal of Earth Sciences》1977,66(1):34-61
Zusammenfassung Ausgehend von einem Vergleich randnaher Normprofile und der faziellen Analyse eines vollständigen Bohrprofils wird für die Randfazies des Unteren Muschelkalkes ein Sedimentationsmodell entwickelt, das auf der Basis klimatisch und epirogenetisch bedingter Untergliederungen des Profils neue Parallelisierungsmöglichkeiten mit beckenwärtigen Faziesbereichen eröffnet.Hervorstechendste Merkmale des Bohrprofils sind rhythmisches Auftreten von Magnesit — der als sedimentäre Bildung bislang nur in Zusammenhang mit chloridischen Evaporiten bekannt war —, eine sedimentologisch und geochemisch begründete zyklische Gliederung sowie intensive Bioturbation und zugleich durchgehende Vergipsung.Die Zyklen sind formal gekennzeichnet durch Koppelung von tonigem Sandstein mit geringen Eisen- und hohen Magnesiumgehalten einerseits und von rotem Ton und Silt mit hohen Eisen- und niedrigen Magnesiumwerten andererseits. Die Zyklen werden als Wechselfolge von litoralen Sedimentationsphasen in subtropischem Klima und Abschnürungsphasen mit Hungersedimentation in aridem Klima interpretiert. Der syndiagenetisch gebildete Magnesit ist dabei Tonsedimentationsphasen genetisch zugeordnet. Anhand der Verteilung der vier nicht-detritischen Hauptminerale Dolomit, Gips, Anhydrit und Magnesit wird der Diageneseablauf rekonstruiert.Nach einer Diskussion der Bildungsumstände und der Korrelierbarkeit bieten sich die Werksteinzone der Randfazies und die Spiriferinabank der Beckenfazies als sedimentologische Zeitmarke an.
A depositional model of the marginal facies of the Lower Muschelkalk (Middle Triassic) is developed by comparison of near-marginal profiles and a facies analysis of a complete drilling record. It is based upon climatologically and epirogenetically caused partitions of the profile and opens new possibilities of correlation with basinal areas.Significant features of the drilling record are rhythmic occurrences of magnesite in sediments only known in connection with chloridic evaporites, a cyclic deposition based on sedimentological and geochemical criteria, and intensive bioturbation with a gypsification throughout.The cycles are formally marked by the correlation of clayey sandstone with low iron and high magnesium contents at the one hand and of red clay and silt with high iron and low magnesium values at the other hand. The cycles are interpreted as an alternation of littoral sedimentation under a subtropical climate and of stages of lagoonal conditions or emersion under an arid climate. The magnesite syndiagenetically formed is genetically attached to stages of clay sedimentation. The process of diagenesis is reconstructed studying the distribution of four main non-detrital minerals: dolomite, gypsum, anhydrite, and magnesite.After discussion of the depositional conditions and the possibilities of correlation, the Werkstein-Zone of the marginal facies and the Spiriferina-Bank of the basinal facies are thought to be sedimentological time markers.
Résumé Une conception de la formation du facies marginal du Muschelkalk inférieur est développée sur la base d'une comparaison entre les profils normés de la région de sondage Mersch/Luxembourg et l'analyse facielle du profil complet de la carotte de ce sondage. A partir des divisions en partie causées par les climats et par des mouvements épirogénétiques, cette conception donne une nouvelle possibilité de corrélation avec le facies situé plus au centre du bassin sédimentaire.Le forage étudié est caractérisé par la présence rythmique de magnésite, qui, jusqu'à présent, était seulement connu en tant que formation sédimentaire, avec des évaporites, par une répartition cyclique basée sur des observations sédimentologiques et géochimiques et par une bioturbation intensive ainsi qu'une gypsification générale.Les cycles sont caractérisés formellement par le couplage d'un grès argileux à faible teneur en fer et à forte teneur en magnésium d'une part et d'argile rouge à forte teneur en fer et à faible teneur en magnésium d'autre part. Les cycles sont interpretés comme une séquence alternante comprenant une sédimentation littorale en climat subtropical et une sédimentation lagunaire ou d'émersion en climat aride. La magnésite formée syndiagénétiquement est donc coordonnée à une phase sédimentaire argileuse. Le cours de la diagénèse est reconstruit à partir de l'étude de la répartition des quatre minéraux principaux non-détriques: dolomite, gypse, anhydrite et magnésite.A la suite de la discussion des conditions de formation et des possibilités de corrélation la « Werkstein-Zone » du facies marginal et la « Spiriferina-Bank » du facies central apparaissent comme des indicateurs sédimentologiques chronostratigraphiques.
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148.
Professor Baurat h. c. Dr.-Ing. Dr. mont. h. c. Leopold Müller-Salzburg Dr.-Ing. Hans -Joachim Schneider 《International Journal of Earth Sciences》1977,66(1):723-739
Zusammenfassung Die Entwicklung der Technik führt zu immer größeren Bauprojekten im Bereich des Talsperrenbaus, Verkehrswegebaus, Untertagebaus, Bergbaus und Grundbaus. Diese großen Bauprojekte stellen in vielfacher Hinsicht eine erhebliche Belastung der Natur sowie eine Beeinträchtigung ihres Gleichgewichts dar und rufen teilweise unvorhergesehene Wechselwirkungen von Bauwerk und Baugrund hervor. Die technische Entwicklung überrollte die Natur so stürmisch, daß ihre ökologischen Folgen weder von den Wissenschaftlern noch von den Praktikern erkannt und bedacht wurden. Die Aufgaben, die sich in diesem Rahmen dem Ingenieurgeologen stellen, bestehen nicht nur in der möglichst genauen Erfassung der geologischen Parameter zur Gewährleistung der Sicherheit des Bauwerks, wirtschaftlich vertretbarer Baukosten unter optimaler Berücksichtigung geologischer Gegebenheiten, sondern sie haben auch die Vorhersage der Wechselwirkungen von Bauwerk und Baugrund sowie von Störungen des oft erstaunlich labilen Gleichgewichts von Geo-, Bio- und Atmosphäre einzubeziehen. Dabei spielen oft rezente geologische Vorgänge eine bisher in der Ingenieurgeologie viel zu wenig gewürdigte Rolle. Die Notwendigkeit, die Ingenieurgeologie schon bei der allerersten Planung, beim Entwurf und der Bauwerksüberwachung mitbestimmen zu lassen, wird an einzelnen Projekten erläutert.
Summary Technical development leads to dams, roads, tunnels, mines and foundations of always larger dimensions. Various aspects of these projects represent a serious encumbrance of nature and an impairment of her equilibrium and can cause unforeseen interactions between structure and the earth. Development has taken place so quickly, that the ecological consequences have not been recognised or considered in many cases — neither by the scientists nor by the practitioners. The tasks, confronting the engineering geologists in this regard, consist not only in an exact investigation of the geological parameters to guarantee the safety of the construction project and to achieve project costs by taking into consideration the geological conditions, but must encompass the recognition of the interactions of construction and the earth as well as the disturbance of the often astonishingly fragile equilibrium of the geo-, bio- and atmosphere. Specifically recent geological processes are often not accounted for, despite their possibly disadvantageous effects. The necessity, that the engineering geologist contributes in all project stages from the first planning, to the design upto the surveillance of the construction, is stressed by giving examples.
Résumé Le développement technique a conduit à des projets de construction toujour plus grands dans le domain des barrages, des routes, des tunnels, des mines et des fondations. Ces grands projets représentent sous beaucoup d'aspects une immense contreinte pour l'environnement naturel, un préjudice pour son équilibre et conduisent parfois à une interaction imprévue entre la construction et le sol. Le développement fut si rapide que les conséquences écologiques ne furent pas reconnues et prises en compte, ni par la science ni par la pratique. Les taches, qui se présentent au géologue ingénieur sur le terrain, comprennent non seulement l'investigation exacte des paramètres géologiques dans le but d'assurer la securité de la construction pour des frais raisonnables tout en prenant en compte d'une façon optimale les conditions géologiques, mais aussi la prévision de ces interactions entre l'ouvrage et le sol, ainsi que les perturbations de l'équilibre de l'environnement géologique, biologique et atmosphérique, équilibre qui est souvent éxtrêmement fragile.Les phénomènes géologiques récents ne sont que très peu considérés dans ces études. La necessité de la participation du géologue ingénieur dès le début des études pendant la conception et la surveillance de l'ouvrage est illustrée à l'aide de projets particuliers.
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149.
Dr. Rüdiger Leggewie Prof. Dr. Hans Füchtbauer Dr. Ramadan El-Najjar 《International Journal of Earth Sciences》1977,66(1):551-577
The Lower Triassic Buntsandstein red beds in Germany were deposited in a river system discharging into a northern basin of varying salinity. In this basin, the main direction of material transport was probably towards the Southeast (Poland), where occasional outlets were open. The median grain size of the fluvial sandstones decreases towards the North (fig. 6): Near the delta, they are finer than the sandstones in the northern basin. This observation together with the differences in feldspar and rock fragments composition indicate that the river system did not contribute to the basin sandstones. Characteristic rock fragments made it possible to estimate the influence of an eastern tributary. The sand size rock fragments can only in part be traced back into conglomerates that occur near the Bohemian Forest, in the Black Forest, and in the Vosges. Most of the debris of the fluvial sandstones derived from the southern rim of the Paris basin, though according to a material balance, a major contribution came from the “Vindelician Ridge” (S. Germany). Abrasion of the rock fragments due to transport is shown by their grain size distribution. 相似文献
150.
Prof. Dr. Hans G. Wunderlich 《International Journal of Earth Sciences》1974,63(2):755-772
The crustal plate of Southern Germany models, in a highly instructive way, the real behaviour of continental crustal plates in the immediate foreland of an active orogenic mountain belt. The frontier line between alpidic and outer-alpine strain pattern crossed this first order tectonic unit. During Upper Tertiary times, the crustal plate of Southern Germany shows an anticlockwise rotation of the direction of maximal principal stress (from NNE/SSW through NNW/SSE to NW/SE), nearly contemporaneous to the transition from alpine Flysch-to Molasse-to postorogenic sedimentation. From prae-Upper Cretaceous to Oligocene, NNE-SSW-plate movement follows a direction more or less parallel — not perpendicular — to the North Atlantic midocean ridge. Since the Pliocene, the axis of tectonic transport (a in rock fabrics nomenclature) turns to a more northwesterly-southeasterly position, so nearly becoming to the well known sea-floor spreading concept. But, at that time, alpine orogenesis comes to an end. Today, neither in the Alps nor in their foreland, any adequate subduction zone to counterbalance the opening of the North Atlantic (as supposed by means of paleomagnetic data) still exists. Since early Pliocene time, the Southern Germany crustal plate shows, in spite of the overburden by thick Molasse sediments, neither any subsidence nor underthrusting the Alps, but, on the contrary, uplifting in a magnitude up to more than fivehundred meters, while the opening of the North Atlantic seems to continue. So we find some serious inconsistencies between the so called new global tectonics and the tectonic evolution of the Southern Germany crustal plate. 相似文献