Abstract
The convexity of soil-covered hillslopes has long been recognized to
reflect transport mechanisms of regolith. Intense previous research
using cosmogenic isotopes and numerical models mostly focused on the
influence of tectonics and erosion rates in regions with silicate rocks,
generally downplaying the influence of parameters such as climate,
chemical denudation rates and dust flux. The goal of the current
research is to characterize and understand how hillslope curvature in
carbonate rocks (∂2z/∂x2) vary as a function of precipitation
and dust flux. The study area is located in the Eastern Mediterranean
across a prominent north-to-south gradient in both precipitation (300 to
1000 mm yr-1) and dust flux (150 to 40 g m-2 yr-1). We combine
topographic analysis using high resolution data from airborne LiDAR,
field measurements, and numerical modeling. The soil creep diffusion
coefficient is evaluated using two different methods: (1) Calculated
directly at sites with known cosmogenically-derived erosion rate; (2)
Estimated using numerical models at snmites with known initial hillslope
form at a known point in time such as volcanic cinder cones with known
eruption ages. Initial results indicate that soil-mantled, carbonate
hillslopes in the sub-humid Eastern Mediterranean are convex and
parabolic in form adjacent to the divide and hillslope curvature is
strongly correlated with precipitation in an inverse manner. This
dependency could reflect: (1) soil creep diffusion coefficients which
increase with precipitation, (2) chemical denudation whose relative
fraction of the total denudation increases with precipitation, and (3)
dust flux which decreases with precipitation. The relative contribution
of these 3 components is currently being evaluated. Diffusion
coefficients were estimated based on numerical modeling of
high-resolution, field-measured, hillslope profiles of several cinder
cones, across a rainfall gradient from 600 to 900 mm yr-1, without
apparent variability in the dust flux. Currently obtained values vary
from ~10-2 to ~10-3 m2 yr-1 with no clear-cut precipitation dependency.
Original language | English |
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State | Published - 17 Dec 2014 |
Event | AGU Fall Meeting 2014 - San Francisco, United States Duration: 15 Dec 2014 → 19 Dec 2014 |
Conference
Conference | AGU Fall Meeting 2014 |
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Country/Territory | United States |
City | San Francisco |
Period | 15/12/14 → 19/12/14 |
Keywords
- 1815 Erosion
- HYDROLOGY
- 1826 Geomorphology: hillslope
- 1865 Soils
- 1886 Weathering