2018
DOI: 10.5194/tc-2018-2
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Microtopographic control on the ground thermal regime in ice wedge polygons

Abstract: Abstract. The goal of this research is to constrain the influence of ice wedge polygon topography on near-surface ground temperatures. Because ice wedge polygon topography is prone to rapid change in a changing climate, and because cracking in 10 the ice wedge depends on thermal conditions at the top of the permafrost, feedbacks between topography and ground temperature can shed light on the potential for future ice wedge cracking in the Arctic. We first report on a year of subdaily ground temperature observat… Show more

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Cited by 3 publications
(8 citation statements)
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“…This process likely generated IW 1, and we propose this as a mechanism of IW polygon dynamics over time (Haltigin et al, ). Polygon center‐cooling was also demonstrated in low centered polygons using modeling in Abolt et al (). We believe trough density increases over time as older IWs reach advanced stages of degradation.…”
Section: Discussionmentioning
confidence: 91%
“…This process likely generated IW 1, and we propose this as a mechanism of IW polygon dynamics over time (Haltigin et al, ). Polygon center‐cooling was also demonstrated in low centered polygons using modeling in Abolt et al (). We believe trough density increases over time as older IWs reach advanced stages of degradation.…”
Section: Discussionmentioning
confidence: 91%
“…Our meshes were constructed with a three‐dimensional pie wedge shape, representing an idealized, radially symmetric polygon (Figure ). In each instance, mineral soil extending to a bottom boundary at 50 m depth was overlain by a 30 cm mantle of peat‐rich soil, as observed at a site near Prudhoe Bay, Alaska (Abolt et al, ). This site was proximal to, but outside of, a drained thaw lake basin and was characterized by epigenetic ice wedges (i.e., ice wedges which have developed beneath a stable land surface, rather than one which is aggrading or eroding).…”
Section: Methodsmentioning
confidence: 90%
“…Each of our simulations was constructed within version 0.86 of Amanzi‐ATS (Coon et al, ) (https://github.com/amanzi/ats), an ecohydrology code designed to simulate the ground hydrologic and thermal regimes of variably saturated soils in one, two, or three dimensions. In previous studies, Amanzi‐ATS has been applied and validated in diverse permafrost settings (Atchley et al, ; Harp et al, ; Jafarov et al, ; Schuh et al, ; Sjöberg et al, ), including polygonal terrain, where microtopography was represented employing either simplified 2‐D meshes, or an array of 1‐D meshes (Abolt et al, ; Atchley et al, ; Jan et al, ). At its core, Amanzi‐ATS uses a flexible multiphysics framework to solve simultaneously for conservation of energy and water mass at the surface, in the subsurface, and in the snowpack (Coon et al, ).…”
Section: Methodsmentioning
confidence: 99%
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