Infiltration efficiency and subsurface water processes of a sustainable drainage system and consequences to flood management

Abstract With increased intensity rainfall events globally and urban expansion decreasing permeable surfaces, there is an increasing problem of urban flooding. This study aims to better understand rainfall infiltration into a Sustainable Drainage System (SuDS) permeable pavement, compared with an ad...

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Main Authors: Nicole A. L. Archer, Rachel A. Bell, Andrew S. Butcher, Stephanie H. Bricker
Format: Article
Language:English
Published: Wiley 2020-09-01
Series:Journal of Flood Risk Management
Subjects:
Online Access:https://doi.org/10.1111/jfr3.12629
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spelling doaj-4ec8fefcdad1489686bf661fa6a808e02020-11-25T03:19:27ZengWileyJournal of Flood Risk Management1753-318X2020-09-01133n/an/a10.1111/jfr3.12629Infiltration efficiency and subsurface water processes of a sustainable drainage system and consequences to flood managementNicole A. L. Archer0Rachel A. Bell1Andrew S. Butcher2Stephanie H. Bricker3British Geological Survey, The Lyell Centre Edinburgh UKBritish Geological Survey, Environmental Science Centre Nottingham UKBritish Geological Survey Oxfordshire UKBritish Geological Survey, Environmental Science Centre Nottingham UKAbstract With increased intensity rainfall events globally and urban expansion decreasing permeable surfaces, there is an increasing problem of urban flooding. This study aims to better understand rainfall infiltration into a Sustainable Drainage System (SuDS) permeable pavement, compared with an adjacent Green Area of made ground, in relationship to groundwater levels below both areas. Both areas were instrumented with soil water content and matric potential sensors and four shallow boreholes were instrumented with groundwater level sensors. Surface infiltration rates were measured using a double‐ring infiltrometer. Results showed that average infiltration rates of the SuDS (1,925 mm/hr) were significantly higher than the Green Area (56 mm/hr). The SuDS was well designed to transfer rainfall rapidly to the aquifer below, where groundwater levels rapidly rose within 1 hr of a 1 in 30 year event (32.8 mm/hr). In comparison, soil compaction of the made ground Green Area decreased infiltration rates, but still enabled the majority of rainfall events to infiltrate. The aquifer below the Green Area responded more slowly, as lower matrix potentials facilitated water retention in the soil profile, slowing water draining to the aquifer. This work reiterates the importance of ensuring a 1 m separation depth between the base of the SuDS infiltration zone and aquifer depth.https://doi.org/10.1111/jfr3.12629groundwaternatural flood managementsustainable drainage systemsurban drainage
collection DOAJ
language English
format Article
sources DOAJ
author Nicole A. L. Archer
Rachel A. Bell
Andrew S. Butcher
Stephanie H. Bricker
spellingShingle Nicole A. L. Archer
Rachel A. Bell
Andrew S. Butcher
Stephanie H. Bricker
Infiltration efficiency and subsurface water processes of a sustainable drainage system and consequences to flood management
Journal of Flood Risk Management
groundwater
natural flood management
sustainable drainage systems
urban drainage
author_facet Nicole A. L. Archer
Rachel A. Bell
Andrew S. Butcher
Stephanie H. Bricker
author_sort Nicole A. L. Archer
title Infiltration efficiency and subsurface water processes of a sustainable drainage system and consequences to flood management
title_short Infiltration efficiency and subsurface water processes of a sustainable drainage system and consequences to flood management
title_full Infiltration efficiency and subsurface water processes of a sustainable drainage system and consequences to flood management
title_fullStr Infiltration efficiency and subsurface water processes of a sustainable drainage system and consequences to flood management
title_full_unstemmed Infiltration efficiency and subsurface water processes of a sustainable drainage system and consequences to flood management
title_sort infiltration efficiency and subsurface water processes of a sustainable drainage system and consequences to flood management
publisher Wiley
series Journal of Flood Risk Management
issn 1753-318X
publishDate 2020-09-01
description Abstract With increased intensity rainfall events globally and urban expansion decreasing permeable surfaces, there is an increasing problem of urban flooding. This study aims to better understand rainfall infiltration into a Sustainable Drainage System (SuDS) permeable pavement, compared with an adjacent Green Area of made ground, in relationship to groundwater levels below both areas. Both areas were instrumented with soil water content and matric potential sensors and four shallow boreholes were instrumented with groundwater level sensors. Surface infiltration rates were measured using a double‐ring infiltrometer. Results showed that average infiltration rates of the SuDS (1,925 mm/hr) were significantly higher than the Green Area (56 mm/hr). The SuDS was well designed to transfer rainfall rapidly to the aquifer below, where groundwater levels rapidly rose within 1 hr of a 1 in 30 year event (32.8 mm/hr). In comparison, soil compaction of the made ground Green Area decreased infiltration rates, but still enabled the majority of rainfall events to infiltrate. The aquifer below the Green Area responded more slowly, as lower matrix potentials facilitated water retention in the soil profile, slowing water draining to the aquifer. This work reiterates the importance of ensuring a 1 m separation depth between the base of the SuDS infiltration zone and aquifer depth.
topic groundwater
natural flood management
sustainable drainage systems
urban drainage
url https://doi.org/10.1111/jfr3.12629
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AT andrewsbutcher infiltrationefficiencyandsubsurfacewaterprocessesofasustainabledrainagesystemandconsequencestofloodmanagement
AT stephaniehbricker infiltrationefficiencyandsubsurfacewaterprocessesofasustainabledrainagesystemandconsequencestofloodmanagement
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