Linking Alpine deformation in the Aar Massif basement and its cover units – the case of the Jungfrau–Eiger mountains (Central Alps, Switzerland)

Abstract. The northwest (NW) rim of the external Aar Massif was exhumed from ∼ 10 km depth to its present position at 4 km elevation above sea level during several Alpine deformation stages. Different models have been proposed for the timing and nature of these stages. Recently proposed exhumation models for the central, internal Aar Massif differ from the ones established in the covering Helvetic sedimentary units. By updating pre-existing maps and collecting structural data, a structural map and tectonic section were reconstructed. Those were interpreted together with microstructural data and peak metamorphic temperature estimates from collected samples to establish a framework suitable for both basement and cover. Deformation temperatures range between 250 and 330 °C, allowing for semi-brittle deformation in the basement rocks, while the calcite-dominated sedimentary rocks deform in a ductile manner at these conditions. Although field data allow to distinguish multiple deformation stages before and during Aar Massif's exhumation, all related structures formed under similar P, T conditions at the investigated NW rim. In particular, we find that the exhumation occurred during two stages of shearing in Aar Massif's basement, which induced in the sedimentary rocks first a phase of folding and then a period of thrusting, accompanied by the formation of a new foliation.

Download Full-text

Linking Alpine deformation in the Aar Massif basement and its cover units – the case of the Jungfrau-Eiger Mountains (Central Alps, Switzerland)

10.5194/se-2018-49 ◽

2018 ◽

Cited By ~ 1

Author(s):

David Mair ◽

Alessandro Lechmann ◽

Marco Herwegh ◽

Lukas Nibourel ◽

Fritz Schlunegger

Keyword(s):

Large Scale ◽

Structural Data ◽

Brittle Deformation ◽

Basement Rocks ◽

Deformation Stages ◽

Metamorphic Temperature ◽

Aar Massif ◽

Multiple Deformation ◽

Exhumation History ◽

Peak Metamorphic Temperature

Abstract. The NW rim of the external Aar Massif was exhumed from ~ 10 km depth to its present position at 4 km elevation above sea level during several Alpine deformation stages. Different models have been proposed for the timing and nature of these stages. Recently proposed exhumation models for the central, internal Aar Massif differ from the ones established in the covering Helvetic sedimentary units. By updating pre-existing maps and collecting structural data, a structural map and tectonic section was reconstructed. Those were interpreted together with micro-structural data and peak metamorphic temperature estimates from collected samples to establish a framework suitable for both basement and cover. Temperatures at deformation ranged from 250 °C to 330 °C allowing for semi-brittle deformation in the basement rocks, while the calcite dominated sediments deform ductile at these conditions. Although field data allows to distinguish multiple deformation stages before and during the Aar Massifs rise, all related structures formed under similar P, T conditions at the investigated NW rim. We find that the exhumation occurred during 2 stages of shearing in the Aar Massif basement, which induced in the sediments first a phase of folding and then a period of thrusting, accompanied by the formation of a new foliation. We can link this uplift and exhumation history to recently published large-scale block extrusion models.

Download Full-text

Geochronology of the Belt Series, Montana

Canadian Journal of Earth Sciences ◽

10.1139/e68-072 ◽

1968 ◽

Vol 5 (3) ◽

pp. 737-747 ◽

Cited By ~ 49

Author(s):

J. D. Obradovich ◽

Z. E. Peterman

Keyword(s):

Average Rate ◽

Sedimentary Rocks ◽

Time Interval ◽

Depositional History ◽

Middle Cambrian ◽

Basement Rocks ◽

Field Evidence ◽

Minimum Age ◽

History Of ◽

Central Montana

This paper presents new radiometric data that permit some qualified statements to be made on the depositional history of the Belt sedimentary rocks. The period of deposition of sedimentary rocks of the Precambrian Belt Series has been placed within a broad time interval, for they rest on metamorphosed basement rock dated at ~ 1800 m.y. and are overlain by the Middle Cambrian Flathead Quartzite (circa 530 m.y.). Prior geochronometric data gathered during the last decade indicate most of the Belt Series to be older than ~ 1100 m.y.K–Ar and Rb–Sr techniques have been applied recently to a variety of samples selected from the whole gamut of the Belt Series. Glauconite from various formations in the sequence McNamara Formation down to the uppermost beds of the Empire Formation in the Sun River area has been dated at 1080 ± 27 m.y. by the K–Ar method and at 1095 ± 22 m.y. by the Rb–Sr mineral isochron method. A Rb–Sr whole-rock isochron based on argillaceous sedimentary rocks from this 5000-ft section gives an age of 1100 ± 53 m.y. The concordance of the preceding results and the K–Ar ages (1075 to 1110 m.y.) on Purcell sills and lava imply that this age represents the time of sedimentation of these units.A Rb–Sr isochron based on whole-rock samples stratigraphically far below the Umpire Formation— the Greyson Shale, Newland Limestone, Chamberlain Shale, and Neihart Quartzite in the Big Belt and Little Beit Mountains—yields an age of 1325 ± 15 m.y. This result is interpreted as indicating a substantial unconformity beneath the Belt Series, at least in central Montana; it also suggests a major hiatus, unsuspected from field evidence, between the uppermost part of the Empire Formation and the Greyson Shale.The results for the youngest of Belt rocks—the Pilcher Quartzite and the Garnet Range Formation, which are exposed in the Alberton region—are equivocal in that there is widespread dispersion. A large component of detrital muscovite in some of the samples could readily account for the magnitude and sense of this dispersion. A maximum age of ~930 m.y. based on an isochron of minimum slope through the various points may be inferred for this sequence. A K–Ar age of 760 m.y. obtained on biotite from a sill in the Garnet Range Formation provides a minimum age for these younger Belt rocks.Three distinct periods of sedimentation for Belt rocks sampled are suggested at ≥ 1300, 1100, and ≤ 900 m.y., with two substantial hiatuses of 200 m.y. or more. In addition the data for the sequence in the Big and Little Belt Mountains suggest that sedimentation may not have commenced for a period of possibly 400 m.y. after the metamorphism that affected basement rocks, while the data for the Garnet Range and Pilcher sequence suggest that sedimentation ceased some 200 to 400 m.y. prior to the deposition of the Middle Cambrian Flathead Quartzite.To suggest that the Belt sediments were deposited continuously over a period of 400 m.y. or more would imply an unusually low average rate of deposition of ≤ 0.1 ft/1000 yr, and this for the thickest part of the Belt Series. As a realistic expression of the depositional history of the Belt Series, both viewpoints are open to question, but the viewpoint that the Belt basin has been characterized by discontinuous sedimentation would be more in keeping with the principle of uniformity.

Download Full-text

Formation of Faden Quartz Druses in Mid-Carboniferous Sandstones of the Donetsk Basin

Advances in Web Technologies and Engineering - Dynamic Knowledge Representation in Scientific Domains ◽

10.4018/978-1-5225-5261-1.ch007 ◽

2018 ◽

pp. 155-162

Author(s):

Oleg Krisak ◽

Vyacheslav Bezrukov

Keyword(s):

Conceptual Framework ◽

Fluid Inclusions ◽

Sedimentary Rocks ◽

Peculiar Feature ◽

Donetsk Basin ◽

Tectonic Regime ◽

Two Stages ◽

Mechanism Of Growth

The chapter addresses the mechanism of growth of druses of faden quartz in a tectonically deformed sandstone. A peculiar feature of this type of quartz, the so-called “white tape” represented by fine subparallel cracks with fluid inclusions, appears highly informative about the genesis of the mineral and tectonic regime of its growth. Two stages of formation of druses of faden quartz are recognized. The suggested mechanism is checked for contradictions by means of the event bush method. The proposed event bush model appears to describe a wider range of quartz formation environments and therefore may serve as a conceptual framework for various models of quartz growth in sedimentary rocks.

Download Full-text

Constraints on temperature–pressure conditions and fluid composition during metamorphism of the Sullivan orebody, Kimberley, British Columbia, from silicate–carbonate equilibria

Canadian Journal of Earth Sciences ◽

10.1139/e95-148 ◽

1995 ◽

Vol 32 (11) ◽

pp. 1937-1949 ◽

Cited By ~ 7

Author(s):

Glen R. De Paoli ◽

David R.M. Pattison

Keyword(s):

British Columbia ◽

Ore Deposits ◽

Garnet Growth ◽

Fluid Composition ◽

Exchange Equilibrium ◽

Low Grade ◽

Metamorphic Temperature ◽

Lower Temperature ◽

Silicate Carbonate ◽

Peak Metamorphic Temperature

The Sullivan mine, in southeastern British Columbia, is one of the world's largest sediment-hosted, massive sulphide deposits. It has undergone at least one period of metamorphism since it was deposited in mid-Proterozoic times. Mineral textures within the deposit are predominantly of metamorphic origin. A well-constrained estimate of metamorphic conditions is required to understand how the original, depositional character of the orebody has been modified by metamorphism. Metamorphic conditions were estimated using multiequilibrium thermobarometric techniques involving silicate–carbonate–fluid equilibria. Peak metamorphic temperature constrained by calibration of the garnet–biotite Fe–Mg exchange equilibrium is 450 ± 50 °C. Lower temperature estimates from some samples are interpreted to record the temperature of cessation of garnet growth prior to the attainment of peak metamorphic temperature. Peak metamorphic pressure as determined from equilibria applicable to the assemblage garnet–biotite–muscovite–chlorite–calcite–quartz–fluid is 380 ± 100 MPa. The fluid composition accompanying this pressure estimate is [Formula: see text], [Formula: see text]. This estimate is particular to one sample and may not be representative for the deposit as a whole. Metamorphic fluids at the estimated P–T conditions would not have contained significant concentrations of C–O–H–S species other than H2O and CO2. Textural evidence and temperature–pressure results from a titanite-bearing metamorphosed mafic intrusion in the deposit suggest published titanite ages near 1330 Ma in the area of the mine represent the age of the peak metamorphic event. The results of this study carry tectonic implications for the Sullivan area, and may have application to other metamorphosed ore deposits and low-grade metamorphic settings.

Download Full-text

Deformation history of the Marmara Granitoid and implications for a dextral shear zone in NW Anatolia

10.5194/egusphere-egu2020-9231 ◽

2020 ◽

Author(s):

Salim Birkan Bayrak ◽

Işıl Nur Güraslan ◽

Alp Ünal ◽

Ömer Kamacı ◽

Şafak Altunkaynak ◽

...

Keyword(s):

Shear Zone ◽

Boundary Migration ◽

Microstructural Analysis ◽

Structural Data ◽

Ductile Deformation ◽

Brittle Deformation ◽

Deformation History ◽

Shear Sense ◽

History Of ◽

Dextral Shear

Marmara granitoid (47 Ma) is a representative example of the Eocene post-collisional magmatism which produced several granitic plutons in NW Anatolia, Turkey. It is a W-E trending sill-like magmatic body which was concordantly emplaced into the metamorphic basement rocks of Erdek Complex and Saraylar Marble. The granitoid is represented by deformed granodiorite which displays well-developed lineation and foliation in meso-scale defined by the elongation of mica and feldspar crystals and recrystallization of quartz however, in some places, magmatic textures are preserved. Deformed granodiorite is broadly cut by aplitic and pegmatitic dikes and contains mafic enclaves which display the same deformation indicators with the main granitoid.Microstructural analysis shows that the solid-state deformation of the Marmara granitoid is classified as ductile deformation with high temperatures and ductile-to-brittle deformation with relatively lower temperatures. Evidence for the ductile deformation of the granitoid is represented by chessboard extinction of quartz, grain boundary migration (GBM) and subgrain rotation recrystallisation (SGR) which exhibits that the deformation temperature changed from 600 oC to 400oC. Bulging recrystallization (BLG), grain size reduction of amphibole, biotite and plagioclases and microcracks on plagioclases were considered as overlying ductile-to-brittle deformation signatures which develop between 300-<250 oC temperatures.All of these field and micro-structural data collectively suggest that the shear sense indicators such as micafish structures and &#948; type mantled porphyroclasts displayed stair-steppings pointing out to a right lateral movement, indicating that the structural evolution and deformation history of Marmara granitoid was controlled by a dextral shear zone.

Download Full-text

POLITIK KEBUDAYAAN DALAM NOVEL SINDEN KARYA PURWADMADI ADMADIPURWA: KAJIAN SEMIOTIKA ROLAND BARTHES

SEMIOTIKA Jurnal Ilmu Sastra dan Linguistik ◽

10.19184/semiotika.v19i2.10463 ◽

2018 ◽

Vol 19 (2) ◽

pp. 10

Author(s):

Nuri Dwi Vindriana ◽

Sunarti Mustamar ◽

Sri Mariati

Keyword(s):

Structural Data ◽

Literary Work ◽

Roland Barthes ◽

Cultural Issues ◽

Political Issues ◽

Sign System ◽

Political Events ◽

Political Interests ◽

Two Stages ◽

The Impact

This study relies on cultural political issues in the Sinden novel to be analyzed using the concept of Roland Barthes mythology. The mythology looks at the form of speech, including a literary work that reflects and reduces social discourse, cultural, ideological and historical. The method used in this research is a qualitative research method. The analysis has two stages of the sign system. The first system is the sign of denotative sign reading that takes the structural data covering themes, characters, conflicts, and settings that will produce signs. The results mark the first sign of the system as a new marker for a myth reading on both sign system. The reading of the myth in the Sinden novel generates political discourse cultures that reflect events in Indonesia with 1960s background. This study aims to describe the cultural issues covered by political interests and reveal the impact of cultural-political events experienced by the grassroots and increase appreciation of the reader in understanding the Sinden novel.

Download Full-text

Neoproterozoic and post-Caledonian exhumation and shallow faulting in NW Finnmark from K/Ar dating and p/T analysis of fault-rocks

10.5194/se-2018-16 ◽

2018 ◽

Cited By ~ 1

Author(s):

Jean-Baptiste P. Koehl ◽

Steffen G. Bergh ◽

Klaus Wemmer

Keyword(s):

Sedimentary Rocks ◽

Fault Gouge ◽

Fault Rocks ◽

Northern Norway ◽

Basement Rocks ◽

Iapetus Ocean ◽

Tectonic Window ◽

Brittle Faulting ◽

Early Neoproterozoic

Abstract. Well-preserved fault gouge along brittle faults in Paleoproterozoic, volcano-sedimentary rocks of the Raipas Group exposed in the Alta-Kvænangen tectonic window in northern Norway yielded latest Mesoproterozoic (ca. 1050 ± 15 Ma) to mid Neoproterozoic (ca. 825–810 ± 18 Ma) K/Ar ages. Pressure-temperature estimates from microtextural and mineralogy analyses of fault-rocks indicate that brittle faulting may have initiated at depth of 5–10 km during the opening of the Asgard Sea in the latest Mesoproterozoic-early Neoproterozoic (ca. 1050–945 Ma), and continued with a phase of shallow faulting during to the opening of the Iapetus Ocean-Ægir Sea and the initial breakup of Rodinia in the mid Neoproterozoic (ca. 825–810 Ma). The predominance and preservation of synkinematic smectite and subsidiary illite in cohesive and non-cohesive fault-rocks indicate that Paleoproterozoic basement rocks of the Alta-Kvænangen tectonic window remained at shallow crustal levels (

Download Full-text

Metamorphic Temperatures and Pressures across the Eastern Franciscan: Implications for Underplating and Exhumation

Lithosphere ◽

10.2113/2020/8853351 ◽

2020 ◽

Vol 2020 (1) ◽

pp. 1-19

Author(s):

William L. Schmidt ◽

John P. Platt

Keyword(s):

Carbonaceous Material ◽

South Fork ◽

The South ◽

Raman Analysis ◽

Laser Raman ◽

Metamorphic Temperature ◽

Thrust Sheets ◽

Peak Metamorphism ◽

California Coast Ranges ◽

Peak Metamorphic Temperature

Abstract The Eastern Belt of the Franciscan Complex in the northern California Coast Ranges consists of coherent thrust sheets predominately made up of ocean floor sediments subducted in the Early Cretaceous and then accreted to the overriding plate at depths of 25-40 km. Progressive packet accretion resulted in the juxtaposition of a series of thrust sheets of differing metamorphic grades. This study utilizes laser Raman analysis of carbonaceous material to determine peak metamorphic temperatures across the Eastern Belt and phengite barometry to determine peak metamorphic pressures. Locating faults that separate packets in the field is difficult, but they can be accurately located based on differences in peak metamorphic temperature revealed by Raman analysis. The Taliaferro Metamorphic Complex in the west reached 323-336°C at a minimum pressure of ~11 kbar; the surrounding Yolla Bolly Unit 215–290°C; the Valentine Springs Unit 282-288°C at 7.8±0.7 kbar; the South Fork Mountain Schist 314–349°C at 8.6–9.5 kbar, a thin slice in the eastern portion of the SFMS, identified here for the first time, was metamorphosed at ~365°C and 9.7±0.7 kbar; and a slice attributed to the Galice Formation of the Western Klamath Mountains at 281±13°C. Temperatures in the Yolla Bolly Unit and Galice slice were too low for the application of phengite barometry. Microfossil fragments in the South Fork Mountain Schist are smaller and less abundant than in the underlying Valentine Springs Unit, providing an additional method of identifying the boundary between the two units. Faults that record a temperature difference across them were active after peak metamorphism while faults that do not were active prior to peak metamorphism, allowing for the location of packet bounding faults at the time of accretion. The South Fork Mountain Schist consists of two accreted packets with thicknesses of 300 m and 3.5 km. The existence of imbricate thrust faults both with and without differences in peak metamorphic temperature across them provides evidence for synconvergent exhumation.

Download Full-text

From widespread Mississippian to localized Pennsylvanian extension in central Spitsbergen, Svalbard

Solid Earth ◽

10.5194/se-9-1535-2018 ◽

2018 ◽

Vol 9 (6) ◽

pp. 1535-1558

Author(s):

Jean-Baptiste P. Koehl ◽

Jhon M. Muñoz-Barrera

Keyword(s):

Sedimentary Rocks ◽

Fault Zones ◽

Normal Faults ◽

Late Devonian ◽

Growth Strata ◽

Tectonic Events ◽

Basement Rocks ◽

Field Evidence ◽

History Of ◽

Tectonic Settings

Abstract. In the Devonian–Carboniferous, a rapid succession of clustered extensional and contractional tectonic events is thought to have affected sedimentary rocks in central Spitsbergen, Svalbard. These events include Caledonian post-orogenic extensional collapse associated with the formation of thick Early–Middle Devonian basins, Late Devonian–Mississippian Ellesmerian contraction, and Early–Middle Pennsylvanian rifting, which resulted in the deposition of thick sedimentary units in Carboniferous basins like the Billefjorden Trough. The clustering of these varied tectonic settings sometimes makes it difficult to resolve the tectono-sedimentary history of individual stratigraphic units. Notably, the context of deposition of Mississippian clastic and coal-bearing sedimentary rocks of the Billefjorden Group is still debated, especially in central Spitsbergen. We present field evidence (e.g., growth strata and slickensides) from the northern part of the Billefjorden Trough, in Odellfjellet, suggesting that tilted Mississippian sedimentary strata of the Billefjorden Group deposited during active (Late/latest?) Mississippian extension. WNW–ESE-striking basin-oblique faults showing Mississippian growth strata systematically die out upwards within Mississippian to lowermost Pennsylvanian strata, thus suggesting a period of widespread WNW–ESE-directed extension in the Mississippian and an episode of localized extension in Early–Middle Pennsylvanian times. In addition, the presence of abundant basin-oblique faults in basement rocks adjacent to the Billefjorden Trough suggests that the formation of Mississippian normal faults was partly controlled by reactivation of preexisting Neoproterozoic (Timanian?) basement-seated fault zones. We propose that these preexisting faults reactivated as transverse or accommodation cross faults in or near the crest of transverse folds reflecting differential displacement along the Billefjorden Fault Zone. In Cenozoic times, a few margin-oblique faults (e.g., the Overgangshytta fault) may have mildly reactivated as oblique thrusts during transpression–contraction, but shallow-dipping, bedding-parallel, duplex-shaped décollements in shales of the Billefjorden Group possibly prevented substantial movement along these faults.

Download Full-text

Late-stage tectonic evolution of the Al-Hajar Mountains, Oman: new constraints from Palaeogene sedimentary units and low-temperature thermochronometry

Geological Magazine ◽

10.1017/s0016756819001250 ◽

2019 ◽

Vol 157 (7) ◽

pp. 1031-1044 ◽

Cited By ~ 5

Author(s):

A Corradetti ◽

V Spina ◽

S Tavani ◽

JC Ringenbach ◽

M Sabbatino ◽

...

Keyword(s):

Low Temperature ◽

Tectonic Evolution ◽

Sedimentary Rocks ◽

Structural Data ◽

Late Eocene ◽

Seismic Interpretation ◽

Structural Investigations ◽

Mountain Belt ◽

Tethys Ocean ◽

Mountain Chain

AbstractMountain building in the Al-Hajar Mountains (NE Oman) occurred during two major shortening stages, related to the convergence between Africa–Arabia and Eurasia, separated by nearly 30 Ma of tectonic quiescence. Most of the shortening was accommodated during the Late Cretaceous, when northward subduction of the Neo-Tethys Ocean was followed by the ophiolites obduction on top of the former Mesozoic margin. This shortening event lasted until the latest Santonian – early Campanian. Maastrichtian to Eocene carbonates unconformably overlie the eroded nappes and seal the Cretaceous foredeep. These neo-autochthonous post-nappe sedimentary rocks were deformed, along with the underlying Cretaceous tectonic pile, during the second shortening event, itself including two main exhumation stages. In this study we combine remotely sensed structural data, seismic interpretation, field-based structural investigations and apatite (U–Th)/He (AHe) cooling ages to obtain new insights into the Cenozoic deformation stage. Seismic interpretation indicates the occurrence of a late Eocene flexural basin, later deformed by an Oligocene thrusting event, during which the post-nappe succession and the underlying Cretaceous nappes of the internal foredeep were uplifted. This stage was followed by folding of the post-nappe succession during the Miocene. AHe data from detrital siliciclastic deposits in the frontal area of the mountain chain provide cooling ages spanning from 17.3 to 42 Ma, consistent with available data for the structural culminations of Oman. Our work points out how renewal of flexural subsidence in the foredeep and uplift of the mountain belt were coeval processes, followed by layer-parallel shortening preceding final fold amplification.

Download Full-text