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Assessing the hydrologic impacts of soil conservation practices using a field-scale experimental setup and physically based modelling
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  • Simon Ricard,
  • Marc-Olivier Gasser,
  • Colline Gombault,
  • Flora Umuhire,
  • Gi-Mick Wu,
  • Neysa Mireille Sawadogo,
  • Arianne Blais-Gagon,
  • Eduardo Chavez,
  • Jean-Benoît Mathieu,
  • Catherine Bossé,
  • William Huertas,
  • Aubert Michaud
Simon Ricard
Institut de recherche et de developpement en agroenvironnement

Corresponding Author:[email protected]

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Marc-Olivier Gasser
Institut de recherche et de developpement en agroenvironnement
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Colline Gombault
Institut de recherche et de developpement en agroenvironnement
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Flora Umuhire
Institut de recherche et de developpement en agroenvironnement
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Gi-Mick Wu
Institut de recherche et de developpement en agroenvironnement
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Neysa Mireille Sawadogo
Institut de recherche et de developpement en agroenvironnement
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Arianne Blais-Gagon
Institut de recherche et de developpement en agroenvironnement
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Eduardo Chavez
Institut de recherche et de developpement en agroenvironnement
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Jean-Benoît Mathieu
Institut de recherche et de developpement en agroenvironnement
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Catherine Bossé
Institut de recherche et de developpement en agroenvironnement
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William Huertas
Institut de recherche et de developpement en agroenvironnement
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Aubert Michaud
Organisme de bassin versant de la baie Missisquoi (OBVBM
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Abstract

An agricultural experimental setup has been constructed with the aim of assessing the impact of soil conservation practices on surface runoff and water quality. The site is located at Saint-Lambert-de-Lauzon (near Québec City, Canada) and is composed by twelve 624 m 2 catchments for which surface and tillage runoffs, water quality (suspended matter, phosphorus, nitrate-nitrite, dissolved metals), soil physical and chemical properties, and crop yields are monitored. The experimental design allows the comparison of four agricultural treatments: two compaction treatments (with and without soil compaction) and two conservation regimes (conventional and soil conservation agricultural practices), each regime being duplicated three times. Generalized Additive Mixed Model (GAMM) highlighted significant relations between the conservation regimes and suspended matter charges, and surface runoff. In other words, conservation practices allow a significant short-term reduction of suspended matter at the field scale. On the other hand, they appear to favour an increase of surface runoff in the springtime. Since only one three-year rotation cycle has been conducted, no effect was observed on soil properties, and crop yields. Long term impacts of soil conservation practices were estimated by implementing a physically based hydrologic model SWAT over each catchment. Restored soil properties were scenarized using measurements conducted over surrounding unperturbed sites. Modelling results suggest that a restoration of soil physical properties would translate into a moderate decrease surface runoff (-5%) at the field scale. The study brings an advanced and multidimensional understanding of the field-scale processes driving soil health, quantitative hydrology, and water quality. It also quantifies potential long-term benefits of implementing soil conservation practices.
29 Jul 2024Submitted to Hydrological Processes
01 Aug 2024Submission Checks Completed
01 Aug 2024Assigned to Editor
01 Aug 2024Reviewer(s) Assigned
04 Aug 2024Reviewer(s) Assigned
02 Sep 2024Review(s) Completed, Editorial Evaluation Pending
07 Oct 2024Editorial Decision: Revise Major
17 Nov 20241st Revision Received
18 Nov 2024Submission Checks Completed
18 Nov 2024Assigned to Editor
18 Nov 2024Reviewer(s) Assigned
18 Nov 2024Reviewer(s) Assigned