Conceptualization of Arctic Tundra Landscape Transitions Using the Alaska Thermokarst Model

Thermokarst topography forms whenever ice-rich permafrost thaws and the ground subsides due to the volume loss when excess ice transitions to water. The Alaska Thermokarst Model (ATM) is a large-scale, state-and-transition model designed to simulate landscape transitions between landscape units, or...

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Bibliographic Details
Format: Dataset
Language:unknown
Published: International Arctic Research Center (IARC) Data Archive
Subjects:
Thermokarst
tundra
Arctic
Ice
permafrost
Tundra
Alaska
Online Access:https://search.dataone.org/view/dcx_aa670108-94fe-4047-8686-5faefe9910c6_0
id dataone:dcx_aa670108-94fe-4047-8686-5faefe9910c6_0
record_format openpolar
spelling dataone:dcx_aa670108-94fe-4047-8686-5faefe9910c6_0 2024-11-03T19:44:57+00:00 Conceptualization of Arctic Tundra Landscape Transitions Using the Alaska Thermokarst Model ENVELOPE(-180.0,-130.0,75.0,50.0) 2015-09-23T23:32:19.175Z https://search.dataone.org/view/dcx_aa670108-94fe-4047-8686-5faefe9910c6_0 unknown International Arctic Research Center (IARC) Data Archive Thermokarst tundra Dataset dataone:urn:node:IARC 2024-11-03T19:07:33Z Thermokarst topography forms whenever ice-rich permafrost thaws and the ground subsides due to the volume loss when excess ice transitions to water. The Alaska Thermokarst Model (ATM) is a large-scale, state-and-transition model designed to simulate landscape transitions between landscape units, or cohorts, due to thermokarst. The ATM uses a frame-based methodology to track transitions and proportion of cohorts within a 1-km 2 grid cell. In the arctic tundra environment, the ATM tracks landscape transitions between non-polygonal ground (meadows), low center polygons, coalescent low center polygons, flat center polygons, high center polygons, ponds and lakes. The transition from one terrestrial landscape type to another can take place if the seasonal ground thaw penetrates underlying ice-rich soil layers either due to pulse disturbance events such as a large precipitation event, wildfire, or due to gradual active layer deepening. The protective layer is the distance between the ground surface and ice-rich soil. The protective layer buffers the ice-rich soils from energy processes that take place at the ground surface and is critical to determining how susceptible an area is to thermokarst degradation. The rate of terrain transition in our model is determined by the soil ice-content, the drainage efficiency (or ability of the landscape to store or transport water), and the probability of thermokarst initiation. Using parameterizations derived from small-scale numerical experiments, functional responses of landscape transitions will be developed and integrated into NGEE-Arctic climate-scale (CLM) modeling efforts. Dataset Arctic Ice permafrost Thermokarst Tundra Alaska International Arctic Research Center (IARC) Data Archive (via DataONE) Arctic ENVELOPE(-180.0,-130.0,75.0,50.0)
institution Open Polar
collection International Arctic Research Center (IARC) Data Archive (via DataONE)
op_collection_id dataone:urn:node:IARC
language unknown
topic Thermokarst
tundra
spellingShingle Thermokarst
tundra
Conceptualization of Arctic Tundra Landscape Transitions Using the Alaska Thermokarst Model
topic_facet Thermokarst
tundra
description Thermokarst topography forms whenever ice-rich permafrost thaws and the ground subsides due to the volume loss when excess ice transitions to water. The Alaska Thermokarst Model (ATM) is a large-scale, state-and-transition model designed to simulate landscape transitions between landscape units, or cohorts, due to thermokarst. The ATM uses a frame-based methodology to track transitions and proportion of cohorts within a 1-km 2 grid cell. In the arctic tundra environment, the ATM tracks landscape transitions between non-polygonal ground (meadows), low center polygons, coalescent low center polygons, flat center polygons, high center polygons, ponds and lakes. The transition from one terrestrial landscape type to another can take place if the seasonal ground thaw penetrates underlying ice-rich soil layers either due to pulse disturbance events such as a large precipitation event, wildfire, or due to gradual active layer deepening. The protective layer is the distance between the ground surface and ice-rich soil. The protective layer buffers the ice-rich soils from energy processes that take place at the ground surface and is critical to determining how susceptible an area is to thermokarst degradation. The rate of terrain transition in our model is determined by the soil ice-content, the drainage efficiency (or ability of the landscape to store or transport water), and the probability of thermokarst initiation. Using parameterizations derived from small-scale numerical experiments, functional responses of landscape transitions will be developed and integrated into NGEE-Arctic climate-scale (CLM) modeling efforts.
format Dataset
title Conceptualization of Arctic Tundra Landscape Transitions Using the Alaska Thermokarst Model
title_short Conceptualization of Arctic Tundra Landscape Transitions Using the Alaska Thermokarst Model
title_full Conceptualization of Arctic Tundra Landscape Transitions Using the Alaska Thermokarst Model
title_fullStr Conceptualization of Arctic Tundra Landscape Transitions Using the Alaska Thermokarst Model
title_full_unstemmed Conceptualization of Arctic Tundra Landscape Transitions Using the Alaska Thermokarst Model
title_sort conceptualization of arctic tundra landscape transitions using the alaska thermokarst model
publisher International Arctic Research Center (IARC) Data Archive
publishDate
url https://search.dataone.org/view/dcx_aa670108-94fe-4047-8686-5faefe9910c6_0
op_coverage ENVELOPE(-180.0,-130.0,75.0,50.0)
long_lat ENVELOPE(-180.0,-130.0,75.0,50.0)
geographic Arctic
geographic_facet Arctic
genre Arctic
Ice
permafrost
Thermokarst
Tundra
Alaska
genre_facet Arctic
Ice
permafrost
Thermokarst
Tundra
Alaska
_version_ 1814732893100965888

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