Simulating a century of soil erosion for agricultural catchment management

Smith, Hugh G.; Peñuela, Andres; Sangster, Heather; Sellami, Haykel; Boyle, John; Chiverrell, Richard; Schillereff, Daniel; Riley, Mark

doi:10.1002/esp.4375

Cited by 12 publications

(16 citation statements)

References 74 publications

(92 reference statements)

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“…This interpretative description of a phenomenon is key to provide understanding and insight (Bailer-Jones, 2009), which is scientifically relevant on its own. Moreover, erosion models are used to make quantitative predictions and scenariobased simulations about how soil is redistributed in potentially complex landscapes, at multiple spatial and temporal scales (e.g., Eekhout et al, 2018;Panagos et al, 2015;Prasuhn et al, 2013;Shrestha and Jetten, 2018;Smith et al, 2018). Policymakers and stakeholders might find these predictions useful, as they may help substantiate environmentally sensitive decisions regarding soil, water, and food security.…”

Section: Accepted Manuscript 1 Introductionmentioning

confidence: 99%

On the evaluation of soil erosion models: Are we doing enough?

Batista

Davies

Silva

et al. 2019

Earth-Science Reviews

168

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As any model of real-world phenomena, soil erosion models must be tested against empirical evidence to have their performance evaluated. This is critical to develop knowledge and confidence in model predictions. However, evaluating soil erosion models is complicated due to the uncertainties involved in the estimation of model parameters and measurements of system responses. Here, we undertake a term co-occurrence analysis to investigate how model evaluation is approached in soil erosion research. The analysis illustrates how model testing is often neglected, and how model evaluation topics are segregated from current research interests. We perform a meta-analysis of model performance to understand the mechanisms that influence model predictive accuracy. Results indicate that different models do not systematically outperform each other, and that calibration seems to be the main mechanism of model improvement. We review how soil erosion models have been evaluated at different temporal and spatial scales, focusing on the methods, assumptions, and data used for model testing. We discuss the implications of uncertainty and equifinality in soil erosion models, and implement a case study of uncertainty assessment that enables models to be tested as hypotheses. A comment on the way forward for the evaluation of erosion models is presented, discussing philosophical aspects of hypothesis testing in environmental modelling. We refute the notion that soil erosion models can be validated, and emphasize the necessity of defining fit-for-purpose tests, based on multiple sources of data, that allow for a broad investigation of model usefulness and consistency.

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Section: Accepted Manuscript 1 Introductionmentioning

confidence: 99%

On the evaluation of soil erosion models: Are we doing enough?

Batista

Davies

Silva

et al. 2019

Earth-Science Reviews

168

View full text Add to dashboard Cite

show abstract

“…This concept takes heterogeneities into account, which constitutes a key to improving catchment behaviour modelling (López-Vicente et al, 2013). For instance, Smith et al (2018) demonstrated that models that capture the effects of spatial and temporal variations in agricultural and conservation practices on soil erosion and sediment delivery greatly improve the model outcome and facilitate decision making regarding catchment management practices. The difficulty lies in integrating connectivity into models without over-parameterization (Heckmann et al, 2014), because highly parameterized models have operational limitations (Blöschl and Sivapalan, 1995;Lane, Nichols and Paige, 1995;Seyfried and Wilcox, 1995).…”

Section: Introductionmentioning

confidence: 99%

Performance of the LandSoil expert‐based model to map erosion and sedimentation: application to a cultivated catchment in central Belgium

Cantreul

Pineux

Swerts

et al. 2020

Earth Surf Processes Landf

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Intensive agricultural practices on sensitive soils induce high erosion rates in central Belgium. Expert-rules models quantify runoff and erosion at catchment scale, avoiding over-parameterization, and can include some direct or indirect connectivity features. The aim of this article is to test the ability of an expert-based model, LandSoil, to quantify runoff and to locate erosion and sedimentation areas in a small cultivated loamy catchment in Belgium during the years 2014, 2015 and 2016. Spatialized data are important for assessing model outputs and the erosive response. Measurements of runoff and observation of spatial erosion/deposition patterns, especially around major connectivity points, permitted an assessment of the reliability of the model results. Runoff modelling gave contrasting results (good linear adjustment at the outlet of the 83 ha sub-catchment (point 1): r 2 of 0.96, Nash-Sutcliffe criterion of 0.95; less good at the outlet of the 3.9 ha sub-catchment (point 2): r 2 of 0.28, Nash-Sutcliffe criterion of-0.47). For point 2 the poor results are explained by the very few runoff events observed, a scaling effect and the small area with a single land use. Graduated rulers demonstrate that the model is able to provide a coherent pattern of erosion/deposition. The study highlights great sensitivity to the effect of land use, land allocation, landscape design and slope gradients. Grass strips induce deposition of eroded particles when slopes are gentle (< 2%). Woodland strips decrease connectivity by being in the stream but deposit thinner sediment layers. Field boundaries have a role in the transport, but not really the quantity, of sediments. This model validation in the Belgian loess context allows us to use LandSoil in other similar environments in order to estimate the effects of landscape management scenarios.

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“…Field amalgamation due to mechanisation over time, resulting in increased field size and reduced hedgerows, likely increased hillslope soil erosion risk and modified hydrological pathways (Thomas et al, ). However, the impact of cropped field positions on modelled mean suspended sediment yield versus the window of opportunity effect has been reported as 22% and 100%, respectively (Smith et al, ). This suggests the gradual amalgamation of fields is likely to have a minor impact on soil erosion and sediment delivery, particularly considering the low connectivity of the majority of catchment soils.…”

Section: Discussionmentioning

confidence: 99%

Influence of land management on soil erosion, connectivity, and sediment delivery in agricultural catchments: Closing the sediment budget

et al. 2019

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Agricultural land, and arable farming in particular, is commonly associated with increased soil erosion risk. Such systems are most vulnerable during low groundcover periods, but downstream delivery is ultimately controlled by connectivity. This study provides a catchment‐scale sediment budget integrating three discrete but complementary investigations spanning different temporal and spatial scales. The first gives details on suspended sediment fluxes at the catchment outlet (2009–2012). The second provenances sources of fluxes using quantitative sediment fingerprinting. The third sets recent data in a multidecadal (60‐year) context using radiometric (137Cs) field‐scale soil loss estimates. The catchment observatory (11 km2) is low relief with predominantly well‐drained soils and dominated by spring‐sown cereal cropping through the study period. Modelling 137Cs inventory losses across 30 fields provided a catchment‐wide mean soil loss of 2.0 Mg ha−1 yr−1. Although such rates are not atypical of intensively managed agriculture across Europe, they are considerably higher than contemporary sediment export yields of 0.12 Mg ha−1 yr−1 of which fingerprinting revealed that contemporary slope erosion contributed less than 25% (0.03 Mg ha−1 yr−1). No evidence of floodplain or in‐channel sediment storage was consistent with disconnectivity. Instead, it is hypothesised that soil loss is associated with coextraction from root crop harvesting of previously widespread sugar beet crops. Considering that the highest mass‐specific 137Cs concentration occurred during the 1960s, there appears to have been significant depletion of the cumulative 137Cs inventory where root crop harvesting occurred as compared with atmospheric fallout ‘reference sites.' The study highlights the value of multiple methodologies when seeking to understand legacy issues within agricultural catchment settings.

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Simulating a century of soil erosion for agricultural catchment management

Cited by 12 publications

References 74 publications

On the evaluation of soil erosion models: Are we doing enough?

On the evaluation of soil erosion models: Are we doing enough?

Performance of the LandSoil expert‐based model to map erosion and sedimentation: application to a cultivated catchment in central Belgium

Influence of land management on soil erosion, connectivity, and sediment delivery in agricultural catchments: Closing the sediment budget

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