Your search keyword '"Hella Wittmann"' showing total 2 results

1. A test of the cosmogenic10Be(meteoric)/9Be proxy for simultaneously determining basin-wide erosion rates, denudation rates, and the degree of weathering in the Amazon basin

Author

F. von Blanckenburg, H. Roig, Jean-Loup Guyot, Laurence Maurice, Hella Wittmann, Julien Bouchez, Naziano Filizola, N. Dannhaus, Jérôme Gaillardet, and M. Christl

Subjects

Hydrology, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Floodplain, Amazon rainforest, Weathering, 15. Life on land, Structural basin, 010502 geochemistry & geophysics, 01 natural sciences, Sedimentary depositional environment, Geophysics, Denudation, 13. Climate action, Tributary, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes, Bed load

Abstract

We present an extensive investigation of a new erosion and weathering proxy derived from the 10Be(meteoric)/9Be(stable) ratio in the Amazon River basin. This new proxy combines a radioactive atmospheric flux tracer, meteoric cosmogenic 10Be, with 9Be, a trace metal released by weathering. Results show that meteoric 10Be concentrations ([10Be]) and 10Be/9Be ratios increase by >30% from the Andes to the lowlands. We can calculate floodplain transfer times of 2–30 kyr from this increase. Intriguingly however, the riverine exported flux of meteoric 10Be shows a deficit with respect to the atmospheric depositional 10Be flux. Most likely, the actual area from which the 10Be flux is being delivered into the mainstream is smaller than the basin-wide one. Despite this imbalance, denudation rates calculated from 10Be/9Be ratios from bed load, suspended sediment, and water samples from Amazon Rivers agree within a factor of 2 with published in situ 10Be denudation rates. Erosion rates calculated from meteoric [10Be], measured from depth-integrated suspended sediment samples, agree with denudation rates, suggesting that grain size-induced variations in [10Be] are minimized when using such sampling material instead of bed load. In addition, the agreement between erosion and denudation rates implies minor chemical weathering intensity in most Amazon tributaries. Indeed, the Be-specific weathering intensity, calculated from mobilized 9Be comprising reactive and dissolved fractions that are released during weathering, is constant at approximately 40% of the total denudation from the Andes across the lowlands to the Amazon mouth. Therefore, weathering in the Amazon floodplain is not detected.

Published

2015

2. Erosion of the Rwenzori Mountains, East African Rift, from in situ-produced cosmogenic10Be

Author

Hella Wittmann, S. Roller, Matthias Hinderer, and M. Kastowski

Subjects

Atmospheric Science, geography, Rift, Plateau, geography.geographical_feature_category, Ecology, Paleontology, Soil Science, Forestry, Mass wasting, Aquatic Science, Oceanography, Geophysics, Denudation, Space and Planetary Science, Geochemistry and Petrology, East African Rift, Earth and Planetary Sciences (miscellaneous), Erosion, Glacial period, Fault block, Geomorphology, Geology, Earth-Surface Processes, Water Science and Technology

Abstract

[1] High relief and steep topography are thought to result in high erosion rates. In the Rwenzori Mountains of the Albert Rift, East Africa, where more than 3 km of relief have formed during uplift of the Rwenzori fault block, overall low denudation rates prevail. We measured in situ-derived cosmogenic denudation rates of 28.2 to 131 mm/kyr in mountainous catchments, and rates of 7.8 to 17.7 mm/kyr on the adjacent low-relief East African Plateau. These rates are roughly an order of magnitude lower than in other settings of similar relief. We present an extensive geomorphological analysis, and find that denudation rates are positively correlated with relief, hillslope gradient, and channel steepness, indicating that river incision controls erosional processes. In most upper headwater reaches above Quaternary ELA levels (>4500 m a.s.l.), glacial imprinting, inherited from several older and recent minor glaciation stages, prevails. In regions below 4500 m a.s.l., however, mild climatic conditions impede frost shattering, favor dense vegetation, and minimize bare rock areas and associated mass wasting. We conclude that erosion of the Rwenzori Mountains is significantly slower than corresponding rates in other mountains of high relief, due to a combination of factors: extremely dense mountain cloud forest vegetation, high rock strength of gneiss and amphibolite lithologies, and low internal fracturing due to the extensional tectonic setting. This specific combination, unique to this extensional tropical setting, leads to unexpected low erosion rates that cannot outpace post-Pliocene ongoing rock uplift of the Rwenzori fault block.

Published

2012