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Colluvial deposits as a possible weathering reservoir in uplifting mountains
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Journal Article
Colluvial deposits as a possible weathering reservoir in uplifting mountains
2018
Overview
The role of mountain uplift in the evolution of the global climate
over geological times is controversial. At the heart of this debate
is the capacity of rapid denudation to drive silicate weathering,
which consumes CO2. Here we present the results of a 3-D
model that couples erosion and weathering during mountain uplift, in
which, for the first time, the weathered material is traced during
its stochastic transport from the hillslopes to the mountain
outlet. To explore the response of weathering fluxes to
progressively cooler and drier climatic conditions, we run model
simulations accounting for a decrease in temperature with or without
modifications in the rainfall pattern based on a simple orographic
model. At this stage, the model does not simulate the deep water
circulation, the precipitation of secondary minerals, variations in
the pH, below-ground pCO2, and the chemical affinity of the
water in contact with minerals. Consequently, the predicted silicate
weathering fluxes probably represent a maximum, although the
predicted silicate weathering rates are within the range of silicate
and total weathering rates estimated from field data. In all cases,
the erosion rate increases during mountain uplift, which thins the
regolith and produces a hump in the weathering rate evolution. This
model thus predicts that the weathering outflux reaches a peak and
then falls, consistent with predictions of previous 1-D models. By
tracking the pathways of particles, the model can also consider how
lateral river erosion drives mass wasting and the temporary storage
of colluvial deposits on the valley sides. This reservoir is
comprised of fresh material that has a residence time ranging from
several years up to several thousand years. During this period, the
weathering of colluvium appears to sustain the mountain weathering
flux. The relative weathering contribution of colluvium depends on
the area covered by regolith on the hillslopes. For mountains
sparsely covered by regolith during cold periods, colluvium produces
most of the simulated weathering flux for a large range of erosion
parameters and precipitation rate patterns. In addition to other
reservoirs such as deep fractured bedrock, colluvial deposits may
help to maintain a substantial and constant weathering flux in
rapidly uplifting mountains during cooling periods.
