Using a mechanistic model to explain the rising non-linearity in storage discharge relationships as the extent of permafrost decreases in Arctic catchments

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Using a mechanistic model to explain the rising non-linearity in storage discharge relationships as the extent of permafrost decreases in Arctic catchments. / Marion Hinzman, Alexa; Sjöberg, Ylva; Lyon, Steve; Schaap, Peter; van der Velde, Ype.

I: Journal of Hydrology, Bind 612, Nr. Part B, 128162, 2022.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Marion Hinzman, A, Sjöberg, Y, Lyon, S, Schaap, P & van der Velde, Y 2022, 'Using a mechanistic model to explain the rising non-linearity in storage discharge relationships as the extent of permafrost decreases in Arctic catchments', Journal of Hydrology, bind 612, nr. Part B, 128162. https://doi.org/10.1016/j.jhydrol.2022.128162

APA

Marion Hinzman, A., Sjöberg, Y., Lyon, S., Schaap, P., & van der Velde, Y. (2022). Using a mechanistic model to explain the rising non-linearity in storage discharge relationships as the extent of permafrost decreases in Arctic catchments. Journal of Hydrology, 612(Part B), [128162]. https://doi.org/10.1016/j.jhydrol.2022.128162

Vancouver

Marion Hinzman A, Sjöberg Y, Lyon S, Schaap P, van der Velde Y. Using a mechanistic model to explain the rising non-linearity in storage discharge relationships as the extent of permafrost decreases in Arctic catchments. Journal of Hydrology. 2022;612(Part B). 128162. https://doi.org/10.1016/j.jhydrol.2022.128162

Author

Marion Hinzman, Alexa ; Sjöberg, Ylva ; Lyon, Steve ; Schaap, Peter ; van der Velde, Ype. / Using a mechanistic model to explain the rising non-linearity in storage discharge relationships as the extent of permafrost decreases in Arctic catchments. I: Journal of Hydrology. 2022 ; Bind 612, Nr. Part B.

Bibtex

@article{4217098cf0bb4514a597f6e48aac6c8e,
title = "Using a mechanistic model to explain the rising non-linearity in storage discharge relationships as the extent of permafrost decreases in Arctic catchments",
abstract = "The relationship between groundwater and discharge in Arctic and sub-Arctic regions is strongly controlled by permafrost. Previous work has shown that catchments with thawing frozen soils due to the warming climate are expected to show changes in their storage-discharge relationship. In this study, we use a mechanistic modelling approach to demonstrate that a thawing catchment underlain with continuous permafrost undergoes a dramatic change in storage-discharge relationship. We demonstrate that the effect of permafrost thaw, conceptualized as a reduction of an impermeable layer in the subsurface, will likely only be clearly observable as a change in slope of the recession curve of catchments with hillslope gradients>5 %. For flat catchments (<1% hillslope gradient), we find no relation with permafrost extent and change in recession curve slope will likely be dominated by changes in active layer parameters, such as in shallow surface permeability (Hydraulic Conductivity, above permafrost) and shallow surface and subsurface water retention (Specific Yield of Groundwater & Specific Yield of Surface). For mildly sloped Arctic catchments (5 % hillslope gradient), change in recession curve slope is controlled both by changes in permafrost extent and the subsurface flow length and subsurface hydraulic properties for the shallow flow, with minimal impact from overland flow properties and changes in meteorological factors. For moderately sloped Arctic catchments (10 % hillslope gradient), change in recession curve slope change is dominated by changes in permafrost extent, and secondly by changes in the subsurface flow length and subsurface hydraulic properties, with no impact from meteorological factors or changes in overland flow properties. Several of the parameters found to be driving shifts in recession curve slopes in our modeling, such as changes in active layer thickness and the formation of taliks, are more likely than others to evolve with the ongoing Arctic climate change in hillslopes, helping us understand what drives the real-world increases in non-linearity of storage-discharge relationships.",
keywords = "Arctic hydrology, Permafrost, Recession curve, Storage-discharge, Thaw",
author = "{Marion Hinzman}, Alexa and Ylva Sj{\"o}berg and Steve Lyon and Peter Schaap and {van der Velde}, Ype",
note = "CENPERM[2022] Funding Information: This work is part of the research program Netherlands Polar Programme with project number ALWPP.2016.014, which is financed by the Dutch Research Council (NWO). Publisher Copyright: {\textcopyright} 2022",
year = "2022",
doi = "10.1016/j.jhydrol.2022.128162",
language = "English",
volume = "612",
journal = "Journal of Hydrology",
issn = "0022-1694",
publisher = "Elsevier",
number = "Part B",

}

RIS

TY - JOUR

T1 - Using a mechanistic model to explain the rising non-linearity in storage discharge relationships as the extent of permafrost decreases in Arctic catchments

AU - Marion Hinzman, Alexa

AU - Sjöberg, Ylva

AU - Lyon, Steve

AU - Schaap, Peter

AU - van der Velde, Ype

N1 - CENPERM[2022] Funding Information: This work is part of the research program Netherlands Polar Programme with project number ALWPP.2016.014, which is financed by the Dutch Research Council (NWO). Publisher Copyright: © 2022

PY - 2022

Y1 - 2022

N2 - The relationship between groundwater and discharge in Arctic and sub-Arctic regions is strongly controlled by permafrost. Previous work has shown that catchments with thawing frozen soils due to the warming climate are expected to show changes in their storage-discharge relationship. In this study, we use a mechanistic modelling approach to demonstrate that a thawing catchment underlain with continuous permafrost undergoes a dramatic change in storage-discharge relationship. We demonstrate that the effect of permafrost thaw, conceptualized as a reduction of an impermeable layer in the subsurface, will likely only be clearly observable as a change in slope of the recession curve of catchments with hillslope gradients>5 %. For flat catchments (<1% hillslope gradient), we find no relation with permafrost extent and change in recession curve slope will likely be dominated by changes in active layer parameters, such as in shallow surface permeability (Hydraulic Conductivity, above permafrost) and shallow surface and subsurface water retention (Specific Yield of Groundwater & Specific Yield of Surface). For mildly sloped Arctic catchments (5 % hillslope gradient), change in recession curve slope is controlled both by changes in permafrost extent and the subsurface flow length and subsurface hydraulic properties for the shallow flow, with minimal impact from overland flow properties and changes in meteorological factors. For moderately sloped Arctic catchments (10 % hillslope gradient), change in recession curve slope change is dominated by changes in permafrost extent, and secondly by changes in the subsurface flow length and subsurface hydraulic properties, with no impact from meteorological factors or changes in overland flow properties. Several of the parameters found to be driving shifts in recession curve slopes in our modeling, such as changes in active layer thickness and the formation of taliks, are more likely than others to evolve with the ongoing Arctic climate change in hillslopes, helping us understand what drives the real-world increases in non-linearity of storage-discharge relationships.

AB - The relationship between groundwater and discharge in Arctic and sub-Arctic regions is strongly controlled by permafrost. Previous work has shown that catchments with thawing frozen soils due to the warming climate are expected to show changes in their storage-discharge relationship. In this study, we use a mechanistic modelling approach to demonstrate that a thawing catchment underlain with continuous permafrost undergoes a dramatic change in storage-discharge relationship. We demonstrate that the effect of permafrost thaw, conceptualized as a reduction of an impermeable layer in the subsurface, will likely only be clearly observable as a change in slope of the recession curve of catchments with hillslope gradients>5 %. For flat catchments (<1% hillslope gradient), we find no relation with permafrost extent and change in recession curve slope will likely be dominated by changes in active layer parameters, such as in shallow surface permeability (Hydraulic Conductivity, above permafrost) and shallow surface and subsurface water retention (Specific Yield of Groundwater & Specific Yield of Surface). For mildly sloped Arctic catchments (5 % hillslope gradient), change in recession curve slope is controlled both by changes in permafrost extent and the subsurface flow length and subsurface hydraulic properties for the shallow flow, with minimal impact from overland flow properties and changes in meteorological factors. For moderately sloped Arctic catchments (10 % hillslope gradient), change in recession curve slope change is dominated by changes in permafrost extent, and secondly by changes in the subsurface flow length and subsurface hydraulic properties, with no impact from meteorological factors or changes in overland flow properties. Several of the parameters found to be driving shifts in recession curve slopes in our modeling, such as changes in active layer thickness and the formation of taliks, are more likely than others to evolve with the ongoing Arctic climate change in hillslopes, helping us understand what drives the real-world increases in non-linearity of storage-discharge relationships.

KW - Arctic hydrology

KW - Permafrost

KW - Recession curve

KW - Storage-discharge

KW - Thaw

U2 - 10.1016/j.jhydrol.2022.128162

DO - 10.1016/j.jhydrol.2022.128162

M3 - Journal article

AN - SCOPUS:85134880260

VL - 612

JO - Journal of Hydrology

JF - Journal of Hydrology

SN - 0022-1694

IS - Part B

M1 - 128162

ER -

ID: 315704542