Your search keyword '"Alfons Berger"' showing total 6 results

1. Th-Pb ion probe dating of zoned hydrothermal monazite and its implications for repeated shear zone activity: An example from the Central Alps, Switzerland

Author

Thomas Pettke, J. Mullis, Alfons Berger, Christian A. Bergemann, Martin J. Whitehouse, Edwin Gnos, Philip Wehrens, and Emilie Janots

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Geochemistry, Massif, Deformation (meteorology), engineering.material, Fault (geology), 010502 geochemistry & geophysics, Overprinting, 01 natural sciences, Geophysics, Geochemistry and Petrology, Monazite, engineering, Shear zone, 10. No inequality, Quartz, Biotite, Geology, 0105 earth and related environmental sciences

Abstract

Th-Pb age dating of zoned hydrothermal monazite from alpine-type fissures/clefts is a powerful tool for constraining polyphase deformation at temperatures below 350°C and presents an alternative to K/Ar and 40Ar/39Ar dating techniques for dating brittle tectonics. This study considers the relationship between cleft orientations in ductile shear zones and cleft mineral crystallization during subsequent brittle overprinting. In the Grimsel area, located in the Aar Massif of the Central Alps, horizontal clefts formed during a primary thrust dominated deformation, while younger and vertically oriented clefts developed during secondary strike-slip movements. The change is due to a switch in orientation between the principal stress axes σ2 and σ3. The transition is associated with monazite crystallization and chloritization of biotite at around 11.5 Ma. Quartz fluid inclusion data allow a link between deformation stages and temperatures to be established and indicate that primary monazite crystallization occurred in both cleft systems at 300–350°C. While cleft monazite crystallization ceases at ~11 Ma in inactive shear zones, monazite growth, and/or dissolution-reprecipitation continues under brittle deformation conditions in vertical clefts during later deformation until ~7 Ma. This younger shear zone activity occurs in association with dextral strike-slip movement of the Rhone-Simplon fault system. With the exception of varying Th/U values correlated with the degree of oxidation, there is only limited compositional variation in the studied cleft monazites.

Published

2017

2. The accretion of foreland basin sediments during early stages of continental collision in the European Alps and similarities to accretionary wedge tectonics

Author

Alfons Berger, Armin Dielforder, and Marco Herwegh

Subjects

Accretionary wedge, 010504 meteorology & atmospheric sciences, Continental collision, Subduction, Geochemistry, Metamorphism, Orogeny, Imbrication, 010502 geochemistry & geophysics, 01 natural sciences, Diagenesis, Geophysics, 13. Climate action, Geochemistry and Petrology, Foreland basin, Geomorphology, Geology, 0105 earth and related environmental sciences

Abstract

We present structural observations from foreland basin sediments that were incorporated into the orogenic wedge of the central European Alps during early stages of continental collision. Our analysis focuses on the prograde evolution and considers the full history of the sediments ranging from their deposition in the basin to deep burial and metamorphism at temperatures of ~320°C. The tectonic evolution is matched with constraints on the diagenetic alteration of the sediments. For this purpose, we calculate the temperatures and depths of sediment compaction and illitization as well as the associated fluid liberation. The data set highlights that the tectonic incorporation of the sediments into the orogenic wedge was strongly controlled by their diagenetic state. Earliest deformation took place during imbrication and frontal accretion of unconsolidated and fluid-saturated sediments. Ductile folding of the sediments occurred already at this stage and was assisted by particulate flow. With the progressive consolidation of the sediments the elastic strength increased, which resulted in an overall embrittlement. This rheological change is recorded by the onset of out-of-sequence thrusting, brittle faulting, and the formation of massive quartz-calcite veins, which took place in the approximate temperature range of the seismogenic zone (i.e., ~150–350°C). Moreover, widespread pressure solution resulted in the formation of a penetrative cleavage and records slow but long-lasting deformation at low background strain rates. In summary, the prograde tectonic evolution of the frontal Alpine wedge exhibits many similarities with the structural and mechanical evolution of accretionary wedges at active subduction zones.

Published

2016

3. Relating orogen width to shortening, erosion, and exhumation during Alpine collision

Author

Nicolas Bellahsen, Alfons Berger, Romain Bousquet, and Claudio Rosenberg

Subjects

Geophysics, business.product_category, 13. Climate action, Geochemistry and Petrology, Erosion, Flux, Sedimentary rock, Collision, business, Geomorphology, Wedge (mechanical device), Geology

Abstract

We investigate along-strike width changes of the thickened, accreted lower plate (TALP) in the Central and in the Eastern Alps. We set the width of the TALP in relation to the inferred amount of collisional shortening and exhumation along six orogen-scale cross sections. Taking the present-day, along-strike gradients in the amount of collisional shortening to represent the temporal evolution of the collisional wedge, it may be concluded that the cross-sectional area of the TALP diminishes during ongoing shortening, indicating that the erosional flux outpaced the accretionary flux. Higher amounts of collisional shortening systematically coincide with smaller widths of the TALP and dramatic increases of the reconstructed eroded rock column. Higher amounts of shortening also coincide with larger amplitudes of orogen-scale, upright folds, with higher exhumation and with higher exhumation rates. Hence, erosion did play a major role in reducing by >30 km the vertical crustal thickness in order to accommodate and allow shortening by folding. Long-term climate differences cannot explain alternating changes of width by a factor of almost 2 along straight segments of the orogen on length scales less than 200 km, as observed from the western Central Alps to the easternmost Eastern Alps. Sedimentary or paleontological evidences supporting such paleo-climatic differences are lacking, suggesting that erosional processes did not directly control the width of the orogen.

Published

2015

4. Dating brittle tectonic movements with cleft monazite: Fluid-rock interaction and formation of REE minerals

Author

Edwin Gnos, Martin J. Whitehouse, M. Soom, Todd E. Waight, Alfons Berger, Emilie Janots, and Robert Frei

Subjects

geography, geography.geographical_feature_category, Rare-earth element, Geochemistry, Massif, Fission track dating, Transpression, Geophysics, Crenulation, Geochemistry and Petrology, Monazite, Geology, Wall rock, Zircon

Abstract

[1] Two millimeter-sized hydrothermal monazites from an open fissure (cleft) that developed late during a dextral transpressional deformation event in the Aar Massif, Switzerland, have been investigated using electron microprobe and ion probe. The monazites are characterized by high Th/U ratios typical of other hydrothermal monazites. Deformation events in the area have been subdivided into three phases: (D1) main thrusting including formation of a new schistosity, (D2) dextral transpression, and (D3) local crenulation including development of a new schistosity. The two younger deformational structures are related to a subvertically oriented intermediate stress axis, which is characteristic for strike slip deformation. The inferred stress environment is consistent with observed kinematics and the opening of such clefts. Therefore, the investigated monazite-bearing cleft formed at the end of D2 and/or D3, and during dextral movements along NNW dipping planes. Interaction of cleft-filling hydrothermal fluid with wall rock results in rare earth element (REE) mineral formation and alteration of the wall rock. The main newly formed REE minerals are Y-Si, Y-Nb-Ti minerals, and monazite. Despite these mineralogical changes, the bulk chemistry of the system remains constant and thus these mineralogical changes require redistribution of elements via a fluid over short distances (centimeter). Low-grade alteration enables local redistribution of REE, related to the stability of the accessory phases. This allows high precision isotope dating of cleft monazite. 232Th/208Pb ages are not affected by excess Pb and yield growth domain ages between 8.03 ± 0.22 and 6.25 ± 0.60 Ma. Monazite crystallization in brittle structures is coeval or younger than 8 Ma zircon fission track data and hence occurred below 280°C.

Published

2013

5. Alpine orogenic evolution from subduction to collisional thermal overprint: The40Ar/39Ar age constraints from the Valaisan Ocean, central Alps

Author

Michael Wiederkehr, Masafumi Sudo, Romain Bousquet, Alfons Berger, and Stefan M. Schmid

Subjects

Mineral, Subduction, Metamorphic rock, Peak pressure, Geochemistry, Metamorphism, engineering.material, Mineral chemistry, Time gap, Geophysics, Geochemistry and Petrology, engineering, Biotite, Geology

Abstract

[1] The investigated HP/LT metasedimentary units of the Valaisan and adjacent European domains occupy a key position in the Alpine belt for understanding the transition from early subduction-related HP/LT metamorphism to collision-related Barrovian overprint and the evolution of mountain belts in general. The timing of high-pressure metamorphism, subsequent retrogression and following Barrow-type overprint was studied by 40Ar/39Ar dating of biotite and several white mica generations that are well characterized in terms of mineral chemistry, texture and associated mineral assemblages. Four distinct age populations of white mica record peak pressure conditions (42–40 Ma) and several stages of subsequent retrograde metamorphic evolution (36–25 Ma). Biotite isotopic analyses yield consistent apparent ages that cluster around 18–16 Ma for the Barrow-type thermal overprint. The recorded isotopic data reveal a significant time gap in the order of some 20 Ma between subduction-related HP/LT metamorphism and collision-related Barrovian overprint, supporting the notion of a polymetamorphic evolution associated with a bimodal P-T path.

Published

2009

6. On the causes and modes of exhumation and lateral growth of the Alps

Author

Alfons Berger and Claudio L. Rosenberg

Subjects

Paleontology, Tectonics, Geophysics, Geochemistry and Petrology, Metamorphic rock, Upper crust, Front (oceanography), Negative correlation, Deformation (meteorology), Fission track dating, Geomorphology, Geology, Zircon

Abstract

[1] A compilation of the apatite and zircon fission track ages of the Alpine chain points to markedly different patterns of cooling and exhumation of the Eastern Alps compared to the central and Western Alps. The site of exhumation and shortening in the Western Alps migrated outward, whereas it was more stationary in the Eastern Alps, where it created a narrower metamorphic belt. A correlation of these observations to the deep structure of the orogen suggests that north directed, lower crustal wedging induces northward propagation of the deformation and exhumation front in the middle and upper crust of the central and Western Alps. The absence of such lower crustal wedges in the Eastern Alps does not induce a similar shift of deformation but rather a long-term localization of shortening and exhumation in one and the same area, namely, the axial zone of the orogen. A critical review of the temporal correlations between inferred changes in the erosional efficiency of the Alps and tectonic phases points to a negative correlation, and hence no erosional control on the shifts of the deformation front of the Alps. Therefore, we conclude that changes in the deep structure and rheology of the orogen, instead of changes in its erosional efficiency, exerted the prime control on the lateral growth of the Alps.

Published

2009