Your search keyword '"Thiede, Rasmus C."' showing total 6 results

1. Climate-driven sediment aggradation and incision since the late Pleistocene in the NW Himalaya, India.

Author

Dey, Saptarshi, Thiede, Rasmus C., Schildgen, Taylor F., Wittmann, Hella, Bookhagen, Bodo, Scherler, Dirk, Jain, Vikrant, and Strecker, Manfred R.

Subjects

*SEDIMENTATION & deposition, *AGGRADATION & degradation, *PLEISTOCENE Epoch, *CLIMATE change

Abstract

Deciphering the response of sediment routing systems to climatic forcing is fundamental for understanding the impacts of climate change on landscape evolution. In the Kangra Basin (northwest Sub-Himalaya, India), upper Pleistocene to Holocene alluvial fills and fluvial terraces record periodic fluctuations of sediment supply and transport capacity on timescales of 10 3 to 10 5 yr. To evaluate the potential influence of climate change on these fluctuations, we compare the timing of aggradation and incision phases recorded within remnant alluvial fans and terraces with climate archives. New surface-exposure dating of six terrace levels with in-situ cosmogenic 10 Be indicates the onset of incision phases. Two terrace surfaces from the highest level (T1) sculpted into the oldest preserved alluvial fan (AF1) date back to 53.4 ± 3.2 ka and 43.0 ± 2.7 ka (1 σ ). T2 surfaces sculpted into the remnants of AF1 have exposure ages of 18.6 ± 1.2 ka and 15.3 ± 0.9 ka , while terraces sculpted into the upper Pleistocene–Holocene fan (AF2) provide ages of 9.3 ± 0.4 ka (T3), 7.1 ± 0.4 ka (T4), 5.2 ± 0.4 ka (T5) and 3.6 ± 0.2 ka (T6). Together with previously published OSL ages yielding the timing of aggradation, we find a correlation between variations in sediment transport with oxygen-isotope records from regions affected by the Indian Summer Monsoon. During periods of increased monsoon intensity and post-Last Glacial Maximum glacial retreat, aggradation occurred in the Kangra Basin, likely due to high sediment flux, whereas periods of weakened monsoon intensity or lower sediment supply coincide with incision. [ABSTRACT FROM AUTHOR]

Published

2016

2. Large spatial and temporal variations in Himalayan denudation.

Author

Thiede, Rasmus C. and Ehlers, Todd A.

Subjects

*CHEMICAL denudation, *OROGENY, *STRUCTURAL geology, *MONTE Carlo method

Abstract

Abstract: In the last decade growing interest has emerged in quantifying the spatial and temporal variations in mountain building. Until recently, insufficient data have been available to attempt such a task at the scale of large orogens such as the Himalaya. The Himalaya accommodates ongoing convergence between India and Eurasia and is a focal point for studying orogen evolution and hypothesized interactions between tectonics and climate. Here we integrate 1126 published bedrock mineral cooling ages with a transient 1D Monte-Carlo thermal–kinematic erosion model to quantify the denudation histories along ~2700km of the Himalaya. The model free parameter is a temporally variable denudation rate from 50Ma to present. Thermophysical material properties and boundary conditions were tuned to individual study areas. Monte-Carlo simulations were conducted to identify the range of denudation histories that can reproduce the observed cooling ages. Results indicate large temporal and spatial variations in denudation and these are resolvable across different tectonic units of the Himalaya. More specifically, across >1000km of the southern Greater Himalaya denudation rates were highest (~1.5–3mm/yr) between ~10 and 2Ma and lower (0.5–2.6mm/yr) over the last 2My. These differences are best determined in the NW-Himalaya. In contrast to this, across the ~2500km length of the northern Greater Himalaya denudation rates vary over length scales of ~300–1700km. Slower denudation (<1mm/yr) occurred between 10 and 4Ma followed by a large increase (1.2–2.6mm/yr) in the last ~4Ma. We find that only the southern Greater Himalayan Sequence clearly supports a continuous co-evolution of tectonics, climate and denudation. Results from the higher elevation northern Greater Himalaya suggest either tectonic driven variations in denudation due to a ramp-flat geometry in the main décollement and/or recent glacially enhanced denudation. [Copyright &y& Elsevier]

Published

2013

3. Abnormal monsoon years and their control on erosion and sediment flux in the high, arid northwest Himalaya

Author

Bookhagen, Bodo, Thiede, Rasmus C., and Strecker, Manfred R.

Subjects

*ARID regions, *RAINFALL, *EXTREME environments, *CONDENSATION

Abstract

Abstract: The interplay between topography and Indian summer monsoon circulation profoundly controls precipitation distribution, sediment transport, and river discharge along the Southern Himalayan Mountain Front (SHF). The Higher Himalayas form a major orographic barrier that separates humid sectors to the south and arid regions to the north. During the Indian summer monsoon, vortices transport moisture from the Bay of Bengal, swirl along the SHF to the northwest, and cause heavy rainfall when colliding with the mountain front. In the eastern and central parts of the Himalaya, precipitation measurements derived from passive microwave analysis (SSM/I) show a strong gradient, with high values at medium elevations and extensive penetration of moisture along major river valleys into the orogen. The end of the monsoonal conveyer belt is near the Sutlej Valley in the NW Himalaya, where precipitation is lower and rainfall maxima move to lower elevations. This region thus comprises a climatic transition zone that is very sensitive to changes in Indian summer monsoon strength. To constrain magnitude, temporal, and spatial distribution of precipitation, we analyzed high-resolution passive microwave data from the last decade and identified an abnormal monsoon year (AMY) in 2002. During the 2002 AMY, violent rainstorms conquered orographic barriers and penetrated far into otherwise arid regions in the northwest Himalaya at elevations in excess of 3 km asl. While precipitation in these regions was significantly increased and triggered extensive erosional processes (i.e., debris flows) on sparsely vegetated, steep hillslopes, mean rainfall along the low to medium elevations was not significantly greater in magnitude. This shift may thus play an important role in the overall sediment flux toward the Himalayan foreland. Using extended precipitation and sediment flux records for the last century, we show that these events have a decadal recurrence interval during the present-day monsoon circulation. Hence, episodically occurring AMYs control geomorphic processes primarily in the high-elevation arid sectors of the orogen, while annual recurring monsoonal rainfall distribution dominates erosion in the low- to medium-elevation parts along the SHF. [Copyright &y& Elsevier]

Published

2005

4. Climatic control on rapid exhumation along the Southern Himalayan Front

Author

Thiede, Rasmus C., Bookhagen, Bodo, Arrowsmith, J. Ramón, Sobel, Edward R., and Strecker, Manfred R.

Subjects

*FAULT zones, *HYPOTHESIS, *EXHUMATION, *INTERMENT, *CLIMATE change

Abstract

Along the Southern Himalayan Front (SHF), areas with concentrated precipitation coincide with rapid exhumation, as indicated by young mineral cooling ages. Twenty new, young (<1–5 Ma) apatite fission track (AFT) ages have been obtained from the Himalayan Crystalline Core along the Sutlej Valley, NW India. The AFT ages correlate with elevation, but show no spatial relationship to tectonic structures, such as the Main Central Thrust or the Southern Tibetan Fault System. Monsoonal precipitation in this region exerts a strong influence on erosional surface processes. Fluvial erosional unloading along the SHF is focused on high mountainous areas, where the orographic barrier forces out >80% of the annual precipitation. AFT cooling ages reveal a coincidence between rapid erosion and exhumation that is focused in a ∼50–70-km-wide sector of the Himalaya, rather than encompassing the entire orogen. Assuming simplified constant exhumation rates, the rocks of two age vs. elevation transects were exhumed at ∼1.4±0.2 and ∼1.1±0.4 mm/a with an average cooling rate of ∼40–50 °C/Ma during Pliocene–Quarternary time. Following other recently published hypotheses regarding the relation between tectonics and climate in the Himalaya, we suggest that this concentrated loss of material was accommodated by motion along a back-stepping thrust to the south and a normal fault zone to the north as part of an extruding wedge. Climatically controlled erosional processes focus on this wedge and suggest that climatically controlled surface processes determine tectonic deformation in the internal part of the Himalaya. [Copyright &y& Elsevier]

Published

2004

5. Erratum to “Large spatial and temporal variations in Himalayan denudation” [Earth Planet. Sci. Lett. 371–372 (2013) 278–293].

Author

Thiede, Rasmus C. and Ehlers, Todd A.

Published

2013

6. Impact of Late Pleistocene climate variability on paleo-erosion rates in the western Himalaya.

Author

Dey, Saptarshi, Bookhagen, Bodo, Thiede, Rasmus C., Wittmann, Hella, Chauhan, Naveen, Jain, Vikrant, and Strecker, Manfred R.

Subjects

*AGGRADATION & degradation, *PLEISTOCENE Epoch, *SEDIMENTATION & deposition, *SEDIMENT transport, *RIVER sediments, *EROSION

Abstract

It has been proposed that at short timescales of 102–105 yr, climatic variability can explain variations in sediment flux, but in orogens with pronounced climatic gradients rate changes caused by the oscillating efficiency in rainfall, runoff, and/or sediment transport and deposition are still not well-constrained. To explore landscape responses under variable climatic forcing, we evaluate time windows of prevailing sediment aggradation and related paleo-erosion rates from the southern flanks of the Dhauladhar Range in the western Himalaya. We compare past and present 10Be-derived erosion rates of well-dated Late Pleistocene fluvial landforms and modern river sediments and reconstruct the sediment aggradation and incision history based on new luminescence data. Our results document significant variations in erosion rates ranging from 0.1 to 3.4 mm/yr over the Late Pleistocene. We find that, during times of weak monsoon intensity, the moderately steep areas (hillslope angles of 27 ± 13°) erode at lower rates of 0.1–0.4 mm/yr compared to steeper (>40°) crestal regions of the Dhauladhar Range that erode at 0.8−1.3 mm/yr. In contrast, during several millennia of stronger monsoon intensity, both the moderately steep and high slope areas record higher erosion rates (>1-3.4 mm/yr). Lithological clast-count analysis shows that this increase of erosion is focused in the moderately steep areas, where Lesser Himalayan rocks are exposed. Our data thus highlight the highly non-linear response of climatic forcing on landscape evolution and suggest complex depositional processes and sedimentary signals in downstream areas. • Paleo-erosion rates in the Himalaya are modulated by climate forcing. • Erosion rates are higher during episodes of strong monsoon. • Topographic response to climate change is non-linear. • Rapid erosion during short-lived strong monsoon phases result in valley aggradation. [ABSTRACT FROM AUTHOR]

Published

2022