Blanket Peat Restoration: Numerical Study of the Underlying Processes Delivering Natural Flood Management Benefits

Salim Goudarzi; David G. Milledge; Joseph Holden; Martin G. Evans; Timothy E. H. Allott; Emma L. Shuttleworth; Michael Pilkington; Jonathan Walker

doi:10.1029/2020wr029209

Blanket Peat Restoration: Numerical Study of the Underlying Processes Delivering Natural Flood Management Benefits

Salim Goudarzi^* (Corresponding Author), David G. Milledge^* (Corresponding Author), Joseph Holden^* (Corresponding Author), Martin G. Evans^* (Corresponding Author), Timothy E. H. Allott^* (Corresponding Author), Emma L. Shuttleworth^* (Corresponding Author), Michael Pilkington, Jonathan Walker

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

14 Citations (Scopus)

Abstract

Restoration of eroded blanket peatlands through revegetation and gully blocking is observed to also deliver significant natural flood management (NFM) benefits (reduce and delay floodpeaks). But there is a lack of clear understanding regarding how different catchment processes interact/counteract under each intervention scenario. We seek to provide more insight by rigorously calibrating TOPMODEL rainfall-runoff model to different experimental catchments each representing an intervention scenario. Through numerical experimentation with the calibrated parameters, we estimate the impact-magnitude of different processes. Our findings confirm the NFM benefits of these restoration-focused interventions. In both interventions and in our largest storms, both the delay and reduced floodpeaks are primarily due to surface roughness reducing the floodwave speed thus thickening the overland flow; we conceptualize this as an increase in a “kinematic storage.” Impact of gully blocking in increasing kinematic storage is very significant and comparable to that of revegetation alone. Interventions' impact on “static storage” (interception + ponding + evapotranspiration) becomes important for smaller storms. Although interventions always increase lag times, they can be less effective in reducing peak magnitude when maximum rainfall intensity is sustained for durations longer than mean catchment delay. We propose two approaches to further increase catchment's static and kinematic storage. Finally, while our field-scale numerical study contributes to the evidence-base for NFM's effectiveness, it also provides a basis for modeling these interventions in the future. Such catchment-scale numerical studies are necessary to extend our findings to spatial scales where flooding can cause socioeconomic damage, and to provide a tool for optimizing the distributed configuration of these interventions

Original language	English
Article number	e2020WR029209
Number of pages	25
Journal	Water Resources Research
Volume	57
Issue number	4
Early online date	26 Apr 2021
DOIs	https://doi.org/10.1029/2020wr029209
Publication status	Published - Apr 2021
Externally published	Yes

Bibliographical note

Funding Information:
This research was conducted as part of the NERC PROTECT-NFM project (NE/R004587) with a project steering committee including representatives from: CH2M, Environment Agency, IUCN UK Peatland Programme, Moors for the Future Partnership, National Trust, Natural Resources Wales, Risk Management Solutions, SEPA, and United Utilities.

Data Availability Statement

The hydrological data were collected as part of the Making Space for Water projects funded by DEFRA and the UK Environment Agency. The work benefited from feedback from the wider PROTECT project team. The hydrological data used in this research are included in this study: Shuttleworth, Evans, Pilkington, et al. ( 2019 ).

Keywords

TOPMODEL
model calibration
natural flood management
peatland
rainfall-runoff modeling
restoration

Access to Document

10.1029/2020wr029209Licence: CC BY

Goudarzi_etal_WRR_Blanket_Peat_Restoration
© 2021. The Authors. This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited. https://creativecommons.org/licenses/by/4.0/
Final published version, 2.12 MBLicence: CC BY

Cite this

Blanket Peat Restoration: Numerical Study of the Underlying Processes Delivering Natural Flood Management Benefits. / Goudarzi, Salim (Corresponding Author); Milledge, David G. (Corresponding Author); Holden, Joseph (Corresponding Author) et al.
In: Water Resources Research, Vol. 57, No. 4, e2020WR029209, 04.2021.

Research output: Contribution to journal › Article › peer-review

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abstract = "Restoration of eroded blanket peatlands through revegetation and gully blocking is observed to also deliver significant natural flood management (NFM) benefits (reduce and delay floodpeaks). But there is a lack of clear understanding regarding how different catchment processes interact/counteract under each intervention scenario. We seek to provide more insight by rigorously calibrating TOPMODEL rainfall-runoff model to different experimental catchments each representing an intervention scenario. Through numerical experimentation with the calibrated parameters, we estimate the impact-magnitude of different processes. Our findings confirm the NFM benefits of these restoration-focused interventions. In both interventions and in our largest storms, both the delay and reduced floodpeaks are primarily due to surface roughness reducing the floodwave speed thus thickening the overland flow; we conceptualize this as an increase in a “kinematic storage.” Impact of gully blocking in increasing kinematic storage is very significant and comparable to that of revegetation alone. Interventions' impact on “static storage” (interception + ponding + evapotranspiration) becomes important for smaller storms. Although interventions always increase lag times, they can be less effective in reducing peak magnitude when maximum rainfall intensity is sustained for durations longer than mean catchment delay. We propose two approaches to further increase catchment's static and kinematic storage. Finally, while our field-scale numerical study contributes to the evidence-base for NFM's effectiveness, it also provides a basis for modeling these interventions in the future. Such catchment-scale numerical studies are necessary to extend our findings to spatial scales where flooding can cause socioeconomic damage, and to provide a tool for optimizing the distributed configuration of these interventions",

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AU - Evans, Martin G.

AU - Allott, Timothy E. H.

AU - Shuttleworth, Emma L.

AU - Pilkington, Michael

AU - Walker, Jonathan

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ER -

Blanket Peat Restoration: Numerical Study of the Underlying Processes Delivering Natural Flood Management Benefits

Abstract

Bibliographical note

Data Availability Statement

Keywords

Access to Document

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