Solving hindered groundwater dynamics in restored tidal marshes by creek excavation and soil amendments : a model study

Van Putte, Niels; Meire, Patrick; Seuntjens, Piet; Joris, Ingeborg; Verreydt, Goedele; Hambsch, Lorenz; Temmerman, Stijn

Solving hindered groundwater dynamics in restored tidal marshes by creek excavation and soil amendments : a model study

Niels Van Putte, Patrick Meire, Piet Seuntjens (UGent) , Ingeborg Joris, Goedele Verreydt, Lorenz Hambsch and Stijn Temmerman

(2022) ECOLOGICAL ENGINEERING. 178.

Author

Niels Van Putte, Patrick Meire, Piet Seuntjens (UGent) , Ingeborg Joris, Goedele Verreydt, Lorenz Hambsch and Stijn Temmerman

Organization

Department of Data analysis and mathematical modelling

Abstract

Groundwater fluxes in tidal marshes largely control key ecosystem functions and services, such as vegetation growth, soil carbon sequestration, and nutrient cycling. In tidal marshes restored on formerly embanked agricultural land, groundwater fluxes are often limited as compared to nearby natural marshes, as a result of historical agricultural soil compaction. To improve the functioning of restored tidal marshes, knowledge is needed on how much certain design options can optimize soil-groundwater interactions in future restoration projects. Based on measured data on soil properties and tidally induced groundwater dynamics, we calibrated and evaluated a 2D vertical model of a creek-marsh cross-section, accounting for both saturated and unsaturated groundwater flow and solute transport in a variably saturated groundwater flow model. We found that model simulations of common restoration practices such as soil amendments (increasing the depth of porous soil on top of the compact layer) and creek excavation (increasing the creek density) increase the soil aeration depth and time, the drainage depth and the solute flux, and decrease the residence time of solutes in the porewater. Our simulations indicate that increasing the depth to the compact layer from 20 cm to 40 cm, or increasing the creek density from 1 creek to 2 creeks along a 50 m marsh transect (while maintaining the total creek cross-sectional area), in both cases more than doubles the volume of water processed by the marsh soil. We discuss that this may stimulate nutrient cycling. As such, our study demonstrates that groundwater modelling can support the design of marsh restoration measures aiming to optimize groundwater fluxes and related ecosystem services.

Keywords

Groundwater modelling, Solute transport, Tidal marsh restoration, Creek, excavation, Soil amendments, SALT-MARSH, HYDRAULIC CONDUCTIVITY, BIOGENIC SILICA, WATER-FLOW, VEGETATION, HYDROLOGY, SEDIMENTS, PERMEABILITY, RESTORATION, COMPACTION

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Citation

Please use this url to cite or link to this publication: http://hdl.handle.net/1854/LU-01GSFWE76K8XV6725G64TVN14Y

MLA: Van Putte, Niels, et al. “Solving Hindered Groundwater Dynamics in Restored Tidal Marshes by Creek Excavation and Soil Amendments : A Model Study.” ECOLOGICAL ENGINEERING, vol. 178, 2022, doi:10.1016/j.ecoleng.2022.106583.
APA: Van Putte, N., Meire, P., Seuntjens, P., Joris, I., Verreydt, G., Hambsch, L., & Temmerman, S. (2022). Solving hindered groundwater dynamics in restored tidal marshes by creek excavation and soil amendments : a model study. ECOLOGICAL ENGINEERING, 178. https://doi.org/10.1016/j.ecoleng.2022.106583
Chicago author-date: Van Putte, Niels, Patrick Meire, Piet Seuntjens, Ingeborg Joris, Goedele Verreydt, Lorenz Hambsch, and Stijn Temmerman. 2022. “Solving Hindered Groundwater Dynamics in Restored Tidal Marshes by Creek Excavation and Soil Amendments : A Model Study.” ECOLOGICAL ENGINEERING 178. https://doi.org/10.1016/j.ecoleng.2022.106583.
Chicago author-date (all authors): Van Putte, Niels, Patrick Meire, Piet Seuntjens, Ingeborg Joris, Goedele Verreydt, Lorenz Hambsch, and Stijn Temmerman. 2022. “Solving Hindered Groundwater Dynamics in Restored Tidal Marshes by Creek Excavation and Soil Amendments : A Model Study.” ECOLOGICAL ENGINEERING 178. doi:10.1016/j.ecoleng.2022.106583.
Vancouver: 1.
Van Putte N, Meire P, Seuntjens P, Joris I, Verreydt G, Hambsch L, et al. Solving hindered groundwater dynamics in restored tidal marshes by creek excavation and soil amendments : a model study. ECOLOGICAL ENGINEERING. 2022;178.
IEEE: [1]
N. Van Putte et al., “Solving hindered groundwater dynamics in restored tidal marshes by creek excavation and soil amendments : a model study,” ECOLOGICAL ENGINEERING, vol. 178, 2022.

@article{01GSFWE76K8XV6725G64TVN14Y,
  abstract     = {{Groundwater fluxes in tidal marshes largely control key ecosystem functions and services, such as vegetation growth, soil carbon sequestration, and nutrient cycling. In tidal marshes restored on formerly embanked agricultural land, groundwater fluxes are often limited as compared to nearby natural marshes, as a result of historical agricultural soil compaction. To improve the functioning of restored tidal marshes, knowledge is needed on how much certain design options can optimize soil-groundwater interactions in future restoration projects. Based on measured data on soil properties and tidally induced groundwater dynamics, we calibrated and evaluated a 2D vertical model of a creek-marsh cross-section, accounting for both saturated and unsaturated groundwater flow and solute transport in a variably saturated groundwater flow model. We found that model simulations of common restoration practices such as soil amendments (increasing the depth of porous soil on top of the compact layer) and creek excavation (increasing the creek density) increase the soil aeration depth and time, the drainage depth and the solute flux, and decrease the residence time of solutes in the porewater. Our simulations indicate that increasing the depth to the compact layer from 20 cm to 40 cm, or increasing the creek density from 1 creek to 2 creeks along a 50 m marsh transect (while maintaining the total creek cross-sectional area), in both cases more than doubles the volume of water processed by the marsh soil. We discuss that this may stimulate nutrient cycling. As such, our study demonstrates that groundwater modelling can support the design of marsh restoration measures aiming to optimize groundwater fluxes and related ecosystem services.}},
  articleno    = {{106583}},
  author       = {{Van Putte, Niels and  Meire, Patrick and Seuntjens, Piet and  Joris, Ingeborg and  Verreydt, Goedele and  Hambsch, Lorenz and  Temmerman, Stijn}},
  issn         = {{0925-8574}},
  journal      = {{ECOLOGICAL ENGINEERING}},
  keywords     = {{Groundwater modelling,Solute transport,Tidal marsh restoration,Creek,excavation,Soil amendments,SALT-MARSH,HYDRAULIC CONDUCTIVITY,BIOGENIC SILICA,WATER-FLOW,VEGETATION,HYDROLOGY,SEDIMENTS,PERMEABILITY,RESTORATION,COMPACTION}},
  language     = {{eng}},
  pages        = {{15}},
  title        = {{Solving hindered groundwater dynamics in restored tidal marshes by creek excavation and soil amendments : a model study}},
  url          = {{http://doi.org/10.1016/j.ecoleng.2022.106583}},
  volume       = {{178}},
  year         = {{2022}},
}

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Solving hindered groundwater dynamics in restored tidal marshes by creek excavation and soil amendments : a model study

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