Agricultural watershed modeling: a review for hydrology and soil erosion processes

Mello, Carlos Rogério de; Norton, L. D.; Pinto, Leandro Campos; Beskow, Samuel; Curi, Nilton

doi:10.1590/s1413-70542016000100001

Cited by 46 publications

(32 citation statements)

References 88 publications

(91 reference statements)

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“…Since the USLE was originally designed at the plot scale, its use causes issues when used at larger scales with more complex topography. R/USLE compensates for this by using a Geographic Information System (GIS) method of determining runoff contribution from upstream areas to downstream locations (de Mello et al, 2016). A common criticism of R/USLE is the exclusion of sediment yields from gully, streambank, and streambed erosion.…”

Section: Representing Other Types Of Erosionmentioning

confidence: 99%

“…A review by de Vente & Posen (2005) differs by focusing on semi-quantitative models that include different types of soil erosion in order to estimate basin 10 sediment yield. Other reviews have focused on the use of different types of soil erosion models in particular places, such as Brazilian watersheds for de Mello et al (2016). These papers reviewed soil erosion models in terms of their complexity and input requirements (Aksoy & Kavvas, 2005;Merritt et al, 2003).…”

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confidence: 99%

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A review of the (Revised) Universal Soil Loss Equation (R/USLE): with a view to increasing its global applicability and improving soil loss estimates

Benavidez¹,

Jackson²,

Maxwell³

et al. 2018

Preprint

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Abstract. Soil erosion is a major problem around the world because of its effects on soil productivity, nutrient loss, siltation in water bodies, and degradation of water quality. By understanding the driving forces behind soil erosion, we can more easily identify erosion-prone areas within a landscape and use land management and other strategies to effectively manage the problem. Soil erosion models have been used to assist in this task. One of the most commonly used soil erosion models is 10 the Universal Soil Loss Equation (USLE) and its family of models: the Revised Universal Soil Loss Equation (RUSLE), the Revised Universal Soil Loss Equation version 2 (RUSLE2), and the Modified Universal Soil Loss Equation (MUSLE). This paper reviewed the different components of USLE and RUSLE etc., and analysed how different studies around the world have adapted the equations to local conditions. We compiled these studies and equations to serve as a reference for other researchers working with R/USLE and related approaches. We investigate some of the limitations of R/USLE, such as issues 15 in data-sparse regions, its inability to account for soil loss from gully erosion or mass wasting events, and that it does not predict sediment pathways from hillslopes to water bodies. These limitations point to several future directions for R/USLE studies: incorporating soil loss from other types of soil erosion, estimating soil loss at sub-annual temporal scales, and using consistent units for future literature. These recommendations help to improve the applicability of the R/USLE in a range of geoclimatic regions with varying data availability, and at finer spatial and temporal scales for scenario analysis. 20

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Section: Representing Other Types Of Erosionmentioning

confidence: 99%

mentioning

confidence: 99%

A review of the (Revised) Universal Soil Loss Equation (R/USLE): with a view to increasing its global applicability and improving soil loss estimates

Benavidez¹,

Jackson²,

Maxwell³

et al. 2018

Preprint

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show abstract

“…Modeling is a necessary tool for estimating and quantifying stream flows and other watershed responses to rainfall (Singh et al, 2011). The challenge is to use hydrological processes, properties and state variables correctly in order to quantify the watershed response (Sogbedji and Mclsaac, 2002;Fenicia et al, 2008;von Gunten et al, 2014;Boll et al, 2015;Mello et al, 2016). The model, therefore, has to rely on spatially distributed information in order to include watershed processes linked to hydrological connectivity (Pechlivanidis et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

How pixel size affects a sediment connectivity index in central Belgium

Cantreul

Bielders

Calsamiglia

et al. 2017

Earth Surf Processes Landf

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Connectivity has become an increasingly used concept in hydrological and sediment research. In order to quantify it, various indices have been proposed since the start of the 21st century including the index of connectivity. This index is based on a limited number of factors, the most important one being topography. Sediment connectivity indices values probably depend on the digital elevation model (DEM) resolution. The aim of this study was, first, to compare the effect of DEM pixel size (between 0.25 and 10 m, using an UAV) in the Belgian loess belt, a lowland area. We show that the index values were lower when the pixel size decreased (a difference of about 20% in value between 0.25 and 10 m). In addition, the impact of linear features in the watershed (e.g. grass strip, bank and road) was lower with the largest pixel sizes, and the connectivity pattern was affected with a pixel size of 5 m or more. At lower pixel sizes (1 m or below), some more disconnected regions appeared. These corresponded with zones where there had been water stagnation during and after rainfalls, and was corroborated by field observations. This confirmed the need for a proper resolution according to the objectives of the study. The second aim of this study was to deduce a minimum pixel size for connectivity study, helping local erosion or sedimentation location and consequent land management decisions. In our context, 1 m stands as the optimum DEM resolution. This pixel size permitted location of all ‘key areas’ in terms of erosion. Very high resolutions (<0.5 m) did not generate much more information, and their calculation time was far greater. Copyright © 2017 John Wiley & Sons, Ltd.

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“…Thus, the use of hydrological models has been a very effective tool to support decisions about the future of water resources (Mello et al, 2016). The Distributed Hydrology Soil Vegetation Model (DHSVM) is a physical-distributed model tested and validated in mountainous areas in the state of Montana, USA, notably in the Middle Fork Flathead watershed Vail;Lettenmaier, 1994).…”

Section: Introductionmentioning

confidence: 99%

Hydrological responses to climate changes in a headwater watershed

et al. 2016

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Climate change impacts need to be considered in water resource planning. This work aims to study of the impacts climate change on Lavrinha headwater watershed, located in the Mantiqueira Range, southeastern Brazil. The impacts from climate change (RCP 8.5 scenario) in the Lavrinha watershed runoff were analyzed based on the "Distributed Hydrology Soil Vegetation Model" (DHSVM), forced with the climate simulated for this future climate change scenario. These simulations, in turn, were generated by the Eta regional climate model coupled to Global Climate Model (GCM) HadGEM2-ES for the 2011-2040, 2041-2070 and 2071-2099 periods. The results of this study showed that the runoff is very sensitive to rising temperatures and reduced precipitation, both projected for the RCP 8.5 scenario. The hydrological simulation projected a reduction in the monthly streamflow between 20 and 77% over the twenty-first century , corresponding to drastic reductions in the runoff behavior and consequently in the water production capacity of the region.Index terms: Downscaling; Eta model; DHSVM; hydrological impacts. RESUMOO impacto das mudanças climáticas precisa ser considerado no planejamento dos recursos hídricos. Este trabalho tem por objetivo o estudo dos impactos das mudanças climáticas na bacia de cabeceira Lavrinha, localizada na Serra da Mantiqueira, Sudeste do Brasil. Os impactos oriundos das mudanças climáticas (cenário RCP 8.5) no escoamento da bacia hidrográfica Lavrinha foram analisados com base no modelo "Distributed Hydrology Soil Vegetation Model" (DHSVM), forçado com as condições climáticas simuladas para este cenário futuro de mudanças climáticas. Estas simulações, por sua vez, foram geradas pelo modelo climático regional Eta acoplado ao Modelo Climático Global (MCG) HadGEM2-ES, nos períodos de 2011-2040, 2041-2070 e 2071-2099. Os resultados deste estudo mostraram que a vazão é bastante sensível ao aumento da temperatura e diminuição da precipitação, ambos projetados para o cenário RCP 8.5. A simulação hidrológica projetou uma redução na vazão mensal entre 20 e 77% ao longo do século XXI (2011 a 2099), correspondendo a reduções drásticas no escoamento e, consequentemente, na capacidade de produção de água da região.Termos para indexação: Downscaling; modelo Eta; DHSVM; impactos hidrológicos.

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Agricultural watershed modeling: a review for hydrology and soil erosion processes

Cited by 46 publications

References 88 publications

A review of the (Revised) Universal Soil Loss Equation (R/USLE): with a view to increasing its global applicability and improving soil loss estimates

A review of the (Revised) Universal Soil Loss Equation (R/USLE): with a view to increasing its global applicability and improving soil loss estimates

How pixel size affects a sediment connectivity index in central Belgium

Hydrological responses to climate changes in a headwater watershed

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