The impact of vegetation on erosion in the East-African Rift System: New insights from Chew Bahir, southern Ethiopia

Past studies indicate that landscape evolution on various timescales is influenced by vegetation cover. However, the linkages between vegetation, type, and species distribution and erosion processes and their relationships between landscape steepness and climate are not well understood. In this study, we focus on the active tectonic setting of the East-African Rift System and its complex climatic and biotic environment to explore linkages between millennial-scale denudation rates and landscape steepness, climate, and vegetation. We specifically focus on spaceborne vegetation-height and biomass measurements that may better reflect the impact of vegetation on geomorphic processes when compared to generally used vegetation cover measurements. We present 12 new in situ ¹⁰Be catchment-averaged denudation rates from the tectonically active Chew Bahir area in southern Ethiopia. The sampled catchments comprise a range of denudation rates over one order of magnitude from 0.01 to 0.1 mm/y and largely correlate with rainfall-weighted landscape steepness. We analyze the rates in comparison to previous studies (a) that evaluated the drier central and northern areas of the Kenya Rift to the south of Chew Bahir and (b) that measured denudation rates in the wetter, densely vegetated Rwenzori mountains in Uganda to the west. Rock-strength values between the sites are comparable, although the Rwenzori mountains have undergone rapid Miocene-Pliocene exhumation processes that may have been aided by ubiquitous fractured bedrock. Importantly, we observe a clear impact of biomass on denudation rates. For example, catchments with the same denudation rate and erosional integration timescale but higher biomass can sustain steeper fluvial channels as indicated by their river-steepness indices. We argue that high vegetation heights characterized by deep root structures lead to a stabilization of hillslopes and ultimately allow the formation of steeper channels. This in turn results in lower denudation rates comparable to less vegetated terrain where hillslopes destabilize more rapidly. We analyze the spatial distribution of hillslopes, river-steepness, rainfall, and vegetation biomass within catchments to elucidate their relative impact. This allows us demonstrate the usefulness of vegetation height and biomass measurements for assessing impacts on erosion rates and we explore different weighting schemes for digital elevation model analysis.