Insight into sediment transport processes on saline rangeland hillslopes using three‐dimensional soil microtopography changes |
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| Authors: | Sayjro K Nouwakpo Mark A Weltz Kenneth C McGwire Jason C Williams Al‐Hamdan Osama Colleen HM Green |
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| Affiliation: | 1. Natural Resources and Environment Sciences, University of Nevada Reno, Reno, NV, USA;2. Great Basin Rangeland Research Unit, USDA‐Agricultural Research Service, Reno, NV, USA;3. Earth and Ecosystem Sciences, Desert Research Institute, Reno, NV, USA;4. Southwest Watershed Research Center, USDA‐Agricultural Research Service, Tucson, AZ, USA;5. Department of Civil and Architectural Engineering, Texas A&M University ‐ Kingsville, Kingsville, TX, USA;6. National Operations Center, USDI‐Bureau of Land Management, Denver, CO, USA |
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| Abstract: | In arid and semi‐arid rangeland environments, an accurate understanding of runoff generation and sediment transport processes is key to developing effective management actions and addressing ecosystem response to changes. Yet, many primary processes (namely sheet and splash and concentrated flow erosion, as well as deposition) are still poorly understood due to a historic lack of measurement techniques capable of parsing total soil loss into these primary processes. Current knowledge gaps can be addressed by combining traditional erosion and runoff measurement techniques with image‐based three‐dimensional (3D) soil surface reconstructions. In this study, data (hydrology, erosion and high‐resolution surface microtopography changes) from rainfall simulation experiments on 24 plots in saline rangelands communities of the Upper Colorado River Basin were used to improve understanding on various sediment transport processes. A series of surface change metrics were developed to quantify and characterize various erosion and transport processes (e.g. plot‐wide versus concentrated flow detachment and deposition) and were related to hydrology and biotic and abiotic land surface characteristics. In general, erosivity controlled detachment and transport processes while factors modulating surface roughness such as vegetation controlled deposition. The extent of the channel network was a positive function of slope, discharge and vegetation. Vegetation may deflect runoff in many flow paths but promoted deposition. From a management perspective, this study suggests that effective runoff soil and salt load reduction strategies should aim to promote deposition of transported sediments rather than reducing detachment which might not be feasible in these resource‐limited environments. Copyright © 2016 John Wiley & Sons, Ltd. |
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| Keywords: | soil microtopography DEM soil erosion deposition sediment transport |
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