Olivia Steinemann’s research while affiliated with ETH Zurich and other places
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The Tamins rock avalanche lies adjacent to the Flims rock avalanche, the largest in the Alps. Its deposit forms a ridge across the Rhine Valley just downstream of the confluence of the Vorderrhein and Hinterrhein rivers. The deposit is dominated by a 1.6-km-long longitudinal ridge, Ils Aults, and two roughly 600-m-long transverse ridges. Several extensional scarps bear witness to spreading of the deposit. A breach through the deposit, where the Rhine River presently flows, reveals a carapace and intense fragmentation. Exposure dating using cosmogenic ³⁶ Cl yields an age of 9420 ± 880 years. This suggests that the Tamins event occurred in a time frame similar to the Flims event but was slightly earlier than the Flims rock avalanche, as also required by stratigraphic relationships. 3D volume modeling reveals bulking of only 14%. The motion of the rock avalanche seems to have occurred first as a flexible block, which underwent fragmentation and simple shearing where the top moved faster than the bottom. The ensuing spreading led to the formation of extensional scarps. There is no identified weak layer along the sliding surface; nevertheless, modeling suggests a friction angle of 10°.
The retreat of glaciers since the Last Glacial Maximum in the European Alps has left an imprint on topography through various erosional processes. However, few methods are currently capable of resolving these mechanisms on Late Glacial to Holocene timescales. Quantifying the relative contributions of mountain erosion, during these different climate cycles, is useful for understanding long-term landscape evolution and the links between global climate and erosion. Here, we combine three optically stimulated luminescence (OSL) exposure dating signals with 10Be surface exposure dating to constrain the post-glacier erosion rates of bedrock samples adjacent to the Gorner Glacier in the European Alps. The results reveal erosion rates of the order of 10-2 to 10-1 mma-1, in general agreement with other studies in the region, as well as a strong negative correlation between erosion rate and elevation, suggesting that frost crack weathering is perhaps not the dominant form of post-glacier weathering. Finally, a global compilation of both subglacial and periglacial erosion rates shows that periglacial erosion rates could be greater than previously thought. Yet subglacial erosion remains higher, implying that it continues to have the stronger influence on shaping landscapes. Therefore, with a changing climate, periglacial erosion rates are likely to remain transient. These insights could lead to important implications for landscape evolution models.
The retreat of glaciers since the Last Glacial Maximum (LGM) in the European Alps has left an imprint on topography through glacial and non-glacial erosional processes. However, few methods are currently capable of resolving these mechanisms on Lateglacial to Holocene timescales. Quantifying the relative contributions of mountain erosion, during these different climate cycles, is useful for understanding long-term landscape evolution and the links between global climate and erosion. Here, we combine three Optically Stimulated Luminescence (OSL) exposure dating signals with 10Be surface exposure dating to constrain the post-glacier erosion rates of bedrock samples down a vertical transect adjacent to the Gorner glacier in Zermatt, Switzerland. The results reveal erosion rates on the order of 10-2 to 10-1 mm a-1, in general agreement with other studies in the region, as well as a strong negative correlation between erosion rates and elevation. Finally, at present glacial erosion is assumed to have a greater influence on landscapes, yet a global compilation of both glacial and non-glacial erosion rates in deglaciated environments shows that erosion rates during interglacial times could be equally important.
We applied a multi-method approach to reconstruct the Gorte rock avalanche (85–95 Mm3) located at the northeastern end of Lake Garda. The combination of field mapping, characterization of bedrock discontinuities, Dan3D-Flex runout modeling and dating of boulders with cosmogenic 36Cl supports the conclusion that the deposits stem from a single rock avalanche at 6.1 ± 0.8 ka. The Gorte event may have triggered the Spiaz de Navesele–Salto della Capra landslide (3.2 Mm3), whose deposits cover the southern end of the Gorte deposits. First-order controls on detachment were the NNE–SSW- and WNW–ESE-oriented fractures in the limestone bedrock, related to the Giudicarie and Schio-Vicenza fault systems, respectively. Dan3D-Flex runout modeling sufficiently reproduced the Gorte rock avalanche, which involved detachment and sliding of a quasi-intact block, likely along marly interbeds, followed by rapid disintegration. The frictional rheology in the source area and the turbulent frictional rheology (Voellmy) in the remaining part best replicate the observed deposit extent and thickness. Heavy precipitation that occurred at that time may have contributed to failure at Gorte. Nonetheless, its timing overlaps with the nearby (<15 km) Dosso Gardene (6630–6290 cal BP) and Marocca Principale (5.3 ± 0.9 ka) landslides, making a seismic trigger plausible.
Understanding how fast glaciers erode their bedrock substrate is one of the key elements in reconstructing how the action of glaciers gives mountain ranges their shape. By combining cosmogenic nuclide concentrations determined in glacially abraded bedrock with a numerical model, we quantify glacial erosion rates over the last 15 ka. We measured cosmogenic 36Cl in fourteen samples from the limestone forefield of the Vorab glacier (Eastern Alps, Switzerland). Determined glacial erosion rates range from 0.01 mm a−1 to 0.16 mm a−1. These glacial abrasion rates differ quite markedly from rates measured on crystalline bedrock (>1 mm a−1), but are similarly low to the rates determined on the only examined limestone plateau so far, the Tsanfleuron glacier forefield. Our data, congruent with field observations, suggest that the Vorab glacier planed off crystalline rock (Permian Verrucano) overlying the Glarus thrust. Upon reaching the underlying strongly karstified limestone the glacier virtually stopped eroding its bed. We attribute this to immediate drainage of meltwater into the karst passages below the glacier, which inhibits sliding. The determined glacial erosion rates underscore the relationship between geology and the resulting landscape that evolves, whether high elevation plateaus in limestone terrains or steep-walled valleys in granitic/gneissic areas.
We constrain the Holocene development of the active Bleis Marscha rock glacier (Err–Julier area, eastern Swiss Alps) with 15 cosmogenic nuclide exposure ages (10Be, 36Cl), horizontal surface creep rate quantification by correlating two orthophotos from 2003 and 2012, and finite element modeling. We used the latter to separate the control on surface movement exerted by topography and material properties. Bleis Marscha is a stack of three overriding lobes whose formation phases are separated by time gaps expressed morphologically as over-steepened terrain steps and kinematically as a sharp downslope decrease in surface movement. The three discrete formation phases appear to be correlated to major Holocene climate shifts: Early Holocene low-elevation lobes (∼8.9–8.0 ka, after the Younger Dryas), Middle Holocene lobe (∼5.2–4.8 ka, after the Middle Holocene warm period), and Late Holocene high-elevation lobes (active since ∼2.8 ka, intermittently coexisting with oscillating Bleis Marscha cirque glacierets). The formation phases appear to be controlled in the source area by the climate-sensitive accumulation of an ice-debris mixture in proportions susceptible to rock glacier creep. The ongoing cohesive movement of the older generations requires ice at a depth which is possibly as old as its Early–Middle Holocene debris mantle. Permafrost degradation is attenuated by “thermal filtering” of the coarse debris boulder mantle and implies that the dynamics of the Bleis Marscha lobes that once formed persisted over millennia are less sensitive to climate. The cosmogenic radionuclide inventories of boulders on a moving rock glacier ideally record time since deposition on the rock glacier root but are stochastically altered by boulder instabilities and erosional processes. This work contributes to deciphering the long-term development and the past to quasi-present climate sensitivity of rock glaciers.
A long-lasting question in glacial geology is how and how fast glaciers were able to shape the distinctive landscapes of the Alps. This study contributes to the understanding on the formation of overdeepened basins, especially the processes and the amount of time involved. We examine the remarkably high (150 m) cross-valley bedrock riegel and the associated overdeepening located in front of the Trift glacier in the central Swiss Alps. A combined approach of field survey with measurements of two cosmogenic nuclides, ¹⁰Be and in-situ ¹⁴C, and a numerical model was used to determine the spatial glacial erosion patterns on the bedrock riegel. Ten samples were taken along two transects; one perpendicular to the glacier flow direction, from outside of the Little Ice Age (LIA) extent down to the centre of the riegel, and the other following the former ice-flow direction across the riegel. Analysis of measured nuclide concentrations shows that the sample outside of the LIA was constantly exposed since the retreat of the Egesen stadial Trift glacier (~11.5 ka). The samples inside the LIA extent indicate a distinct trend of increasing glacial erosion rates from 0 mm/a near the LIA ice margin to high erosion all across the top of the riegel. The resulting minimum glacial erosion rates from samples on the riegel are 0.5–1.1 mm/a (¹⁰Be) and 0.6–>1.8 mm/a (in-situ ¹⁴C) which correspond to minimum erosion depths of 1.6–>3 m (¹⁰Be) and 1–>5 m (¹⁴C). The extremely low nuclide concentrations measured at the riegel highlight the substantial erosion (predominantly abrasion) of the bedrock surface during late Holocene glacier coverage. Field observations suggest that the formation of the overdeepening and, as a consequence, the riegel is due to a combination of valley shape, bedrock structures, glacier confluence and hydrology. We further hypothesise that the gorge is a key factor responsible for this impressive overdeepening, by lowering the threshold for the subglacial meltwater, effectively decoupling the height of the riegel from the depth of the overdeepening.
Zion National Park preserves a rich geological record of Holocene landslide-dammed canyons in its deeply incised topography, with 11 hypothesized valley-blocking deposits within the park boundaries. Despite consistent stratigraphic, tectonic, and climatic settings, the occurrence of and subsequent landscape response to these natural dams varies. As such, the region provides a unique natural laboratory for quantifying the effect and evolution of landslide dams in high-relief canyon topography. Here we present a detailed study of a rock avalanche deposited at the mouth of Hop Valley in Zion National Park, describing its age, size, emplacement conditions, impact on local geomorphology and sedimentology, as well as the subsequent usage of the valley by native Ancestral Puebloans. Topographic reconstructions indicate the original deposit was ~75 million m ³ and 1.5 km long with a maximum thickness of 180 m. New ages from cosmogenic ¹⁰ Be surface exposure dating indicate a single-event failure at 6.7 ± 0.7 ka. The rock avalanche impounded ~55 million m ³ of sediment, transforming Hop Valley from a relatively narrow gorge to a broad flat-floored canyon. Stratigraphic sections of accumulated upvalley sediments, calculated sedimentation rates (averaging 8.2 ± 0.8 m/ky), and paleoclimate records suggest the deposit primarily dammed sediment, rather than water, to produce an extensive alluvial plain. This detailed case-history analysis, together with our review of other Holocene landslide dams in Zion National Park, helps clarify the legacy of valley-blocking mass movements in steep canyon topography.
In this study we reconstructed the Buchwiese rock avalanche in the Lienz Dolomites in Eastern Tyrol (Austria). We used a multi-method approach combining geological field mapping, the analysis of digital elevation model (DEM) data, cosmogen-ic 36 Cl exposure dating, and a geoelectrical survey to unravel the detachment mechanisms, emplacement processes and timing of the Buchwiese rock avalanche. According to the results of the 36 Cl exposure dating, the event took place at 10.8±0.9 ka during the Early Holocene. The failure of a rock mass with a volume of 27x10 6 m 3 was enabled by a dip-slope in strata of the Kössen Formation (limestone, marls, claystone), Oberrhätkalk (massive to thickly bedded limestone), Allgäu Formation (mottled limestone and marl) and Rotkalk (red nodular limestone and marl), in combination with N-S to NNE-SSW trending brittle faults. We regard fatigue of the fine-grained rocks of the Kössen Fm. (claystone, marl), typical slaking rocks, since the Last Glacial Maximum as the major cause for this catastrophic rock slope failure. With the reconstructed drop height (H) of 1200 m and runout length (L) of 3.5 km, the Buchwiese rock avalanche has a Fahrböschung angle α of 19° and H/L ratio of 0.36. Due to the geological conditions, the initial failure occurred as a plane slide. In the deposition area, we observe strong control of lithological properties, topographic conditions, and substrate materials along the pathway on the morphology and sedimentology of the rock avalanche deposit. Longitudinal ridges, indicating spreading of an unconfined flow, are comprised mostly of massive limestone (Oberrhätkalk). The cara-pace facies consisting of clast-supported boulders is only developed in areas with limestone (mostly Oberrhätkalk but also limestone of the Kössen Fm.). The body facies in the upper parts are dominated by jigsaw subfacies with a subordinate occurrence of fragmented subfacies in the outcrops. Even in the middle part of the deposition area, we observe the prevalence of the moderately fragmented jigsaw subfacies within large areas of Kössen Fm. debris, which consists of alternating claystone, limestone beds. Such a finding may indicate preferential deformation within the claystone beds. After partial collision with a bedrock ridge and a small jump, the fragmented subfacies dominates. This collision led to the formation of a fan-like megaboulder cluster consisting of detached and fragmented Oberrhätkalk boulders with volumes up to 1000 m 3 and a fan-like distribution. The results of geoelectrical surveys reflect different amounts of fragmentation with the carapace facies, showing high resistivity, while the body facies reveals low resistivity. Preserved source stratigraphy within the dilated rock mass indicates predominantly laminar rock avalanche movement. All the morphological and sedimentary evidence supports a dynamic fragmentation model as the best mechanical explanation for the Buchwiese rock avalanche.
Determining the sensitivity of the Greenland Ice Sheet (GrIS) to Holocene climate changes is a key prerequisite for understanding the future response of the ice sheet to global warming. In this study, we present new information on the Holocene glacial history of the GrIS in Inglefield Land, north Greenland. We use 10Be and in situ 14C exposure dating to constrain the timing of deglaciation in the area and radiocarbon dating of reworked molluscs and wood fragments to constrain when the ice sheet retreated behind its present-day extent. The 10Be ages are scattered ranging from ca. 92.7 to 6.8 ka, whereas the in situ 14C ages range from ca. 14.2 to 6.7 ka. Almost half of the apparent 10Be ages predate the Last Glacial Maximum and up to 89 % are to some degree affected by nuclide inheritance. Based on the few reliable 10Be ages, the in situ 14C ages and existing radiocarbon ages from Inglefield Land, we find that the deglaciation along the coast commenced at ca. 8.6–8.3 ka cal BP in the western part and ca. 7.9 ka in the central part, following the opening of Nares Strait and arrival of warm waters. The ice margin reached its present-day position at ca. 8.2 ka at the Humboldt Glacier and ca. 6.7 ka in the central part of Inglefield Land. Radiocarbon ages of reworked molluscs and wood fragments show that the ice margin was behind its present-day extent from ca. 5.8 to 0.5 ka cal BP. After 0.5 ka cal BP, the ice advanced towards its Little Ice Age position. Our results emphasize that the slowly eroding and possibly cold-based ice in north Greenland makes it difficult to constrain the deglaciation history based on 10Be ages alone unless they are paired with in situ 14C ages. Further, combining our findings with those of recently published studies reveals distinct differences between deglaciation patterns of northwest and north Greenland. Deglaciation of the land areas in northwest Greenland occurred earlier than in north Greenland, and periods of restricted ice extent were longer, spanning the Middle and Late Holocene. Overall, this highlights past ice sheet sensitivity to Holocene climate changes in an area where little information was available just a few years ago.
... Subaerial erosion rates in alpine environments are typically low (Elkadi et al., 2022;Lehmann et al., 2020), rarely more than 0.001 cm yr -1 . As such, we assume that during periods of exposure, there was negligible subaerial erosion of bedrock surfaces. ...
... Rock avalanches are frequently observed in mountainous regions, characterized by intense fragmentation and disintegration of an initially coherent mass. They typically attain high velocities and long runout distances, forming deposits with significant spread as seen in notable events such as the Films (Pollet et al. 2005), Tamins (Pfiffner et al. 2022), Frank (Cruden and Hungr 1986), and Pink Mountain (Geertsema et al. 2006) rock avalanches. The study of rock avalanche dynamics has long been a focal point and frontier issue in engineering geology. ...
... Mozafari et al. [12], Aksay et al. [13], and Ruggia et al. [14] validated the novel use of cosmogenic nuclides in disentangling the timing of events in natural hazard research and highlighted the importance of such an analysis for risk assessment and hazard mitigation. Mozafari et al. [12] showed the potential of cosmogenic 36 Cl analysis to gather crucial information required for a precise evaluation of seismic risk by exploring normal faults for unknown major prehistorical earthquakes in Western Anatolia, one of the seismically most active extensional regimes of our planet. ...
... In the second group of contributions, Steinemann et al. [8], da Silva Guimarães et al. [9], and Musso et al. [10] delved into the realm of estimating erosion rates using cosmogenic nuclides. Upon quantifying erosion, Steinemann et al. [8] showed that a significant role of glaciers in sculpting mountain landscapes is not only their potential to deeply carve the landscape but also, surprisingly, their ability to not erode the bedrock. ...
... to percolate down into the rock glacier where lower temperatures are found, contributing to refreezing and interstitial ice (Tenthorey 1992). The freeze-thaw process also contributes to mechanical weathering, leading to an increased debris supply (Amschwand et al. 2021). The rock glacier attributes here show clustering at low and high solar radiation and dispersed through mid-solar radiation exposure. ...
... Such ensembles of basins, riegels, and slot canyons (or inner gorges) are common features in Alpine valleys (Fig. 3) and have therefore been the target of previous research. In this context, it was proposed that such gorges and riegels in the Alps were likely shaped during several glacial/interglacial periods (Montgomery and Korup, 2011) and that the incision of the canyons occurred during the decay of glaciers and ice caps, when large volumes of meltwater were released (Steinemann et al., 2021). As a further, yet only partly related, example, erosion by subglacial meltwater was put forward to explain the formation of inner gorges at the margin of the Fennoscandian ice sheet (based on the pattern of surface exposure ages; Jansen et al., 2014), and such a mechanism was used to explain (i) the origin of the deep channels on the floor of the eastern English Channel and (ii) the breaching of the bedrock swell at the Dover Strait during the aftermath of the Marine Isotope Stage (MIS) 12 glaciation or a later glacial period (Gupta et al., 2007(Gupta et al., , 2017Cohen et al., 2014). ...
... Costa and Schuster (1991) archived 13 Austrian landslide dams in a worldwide inventory of historical landslide dams however, the presented information mostly included the locality of the dams and the type of the landslide. In the past twenty years, many studies have been conducted and characterized the landslide dams in Western Austria, Northern Italy, and Bavaria (Felber, 1987;Poschinger and Thom, 1995;Ivy-Ochs et al., 1998;Jerz, 1999;Schrott et al., 2003;Uhlir and Schramm, 2003;Morche et al., 2006;Prager et al., 2006;Reuther et al., 2006;Ostermann et al., 2007;Prager et al., 2008;Cotza, 2009;Gruber et al., 2009;Prager et al., 2009a;Prager et al., 2009b;Panizza et al., 2011;Ostermann et al., 2012;Patzelt, 2012;Starnberger et al., 2013;Stefani et al., 2013;Dufresne et al., 2016;Ostermann and Prager, 2016;Dufresne et al., 2018;Knapp et al., 2020;Ostermann et al., 2020;Reitner et al., 2020;Zangerl et al., 2020). Although, a comprehensive database that encompasses detailed information on the geomorphological and geometrical characteristics of these landslide dams is lacking in the literature. ...
... In W Greenland, glaciers advanced and exceeded their present-day limits at 3.7, 2.8, 1.5 ka, and during the LIA at 1400 and 1700 CE (Schweinsberg et al., 2019). In Inglefield Land, NW Greenland, glaciers remained behind current boundaries from 5.8 ka until the beginning of the LIA at 1450 CE (Søndergaard et al., 2020). The northern GrIS margin also showed a relative stability during the Late Holocene, with only two neoglacial advances of similar magnitude detected at 2.8 ka and 1650 CE (Reusche et al., 2018). ...
... This process can affect the stability of glacial sediments and trigger the readjustment of some boulders, resulting in younger exposure ages (Fernández-Fernández et al., 2020). Other boulders, which would have remained stable for millennia on the glacial surface, were continuously exposed to cosmogenic radiation that resulted in ages pre-dating the stabilization of the deposit (Bibby et al., 2016;Mackay and Marchant, 2016;Amschwand et al., 2020). This may explain the average age of the hummocky terrain samples (12.6 ± 2.2 ka; Fig. 3). ...
... These landforms are highly relevant from a geomorphological and climatic perspective because they play an important role in sediment transfer by transporting large amounts of debris through valley flanks [3,4]. Furthermore, rock glaciers are indicators of the current and past distribution of permafrost in several mountains of the world, such as the European Alps and Tatras mountains [5][6][7], the North-and South American Cordilleras [8][9][10], High Mountain Asia [11][12][13][14], and high latitude regions [15,16]. Moreover, intact rock glaciers (i.e. ...