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Article: Climate change and Arctic ecosystems: 2. Modeling, paleodata-model comparisons, and future projections

TitleClimate change and Arctic ecosystems: 2. Modeling, paleodata-model comparisons, and future projections
Authors
KeywordsIce age
Biome
Biogeography
Vegetation modeling
Tundra
Mammoths
Issue Date2003
Citation
Journal of Geophysical Research D: Atmospheres, 2003, v. 108, n. 19 How to Cite?
AbstractLarge variations in the composition, structure, and function of Arctic ecosystems are determined by climatic gradients, especially of growing-season warmth, soil moisture, and snow cover. A unified circumpolar classification recognizing five types of tundra was developed. The geographic distributions of vegetation types north of 55°N, including the position of the forest limit and the distributions of the tundra types, could be predicted from climatology using a small set of plant functional types embedded in the biogeochemistry-biogeography model BIOME4. Several palaeoclimate simulations for the last glacial maximum (LGM) and mid-Holocene were used to explore the possibility of simulating past vegetation patterns, which are independently known based on pollen data. The broad outlines of observed changes in vegetation were captured. LGM simulations showed the major reduction of forest, the great extension of graminoid and forb tundra, and the restriction of low- and high-shrub tundra (although not all models produced sufficiently dry conditions to mimic the full observed change). Mid-Holocene simulations reproduced the contrast between northward forest extension in western and central Siberia and stability of the forest limit in Beringia. Projection of the effect of a continued exponential increase in atmospheric CO2 concentration, based on a transient ocean-atmosphere simulation including sulfate aerosol effects, suggests a potential for larger changes in Arctic ecosystems during the 21st century than have occurred between mid-Holocene and present. Simulated physiological effects of the CO2 increase (to > 700 ppm) at high latitudes were slight compared with the effects of the change in climate.
Persistent Identifierhttp://hdl.handle.net/10722/268499
ISSN
2015 Impact Factor: 3.318
2020 SCImago Journal Rankings: 1.670
ISI Accession Number ID

 

DC FieldValueLanguage
dc.contributor.authorKaplan, J. O.-
dc.contributor.authorBigelow, N. H.-
dc.contributor.authorPrentice, I. C.-
dc.contributor.authorHarrison, S. P.-
dc.contributor.authorBartlein, P. J.-
dc.contributor.authorChristensen, T. R.-
dc.contributor.authorCramer, W.-
dc.contributor.authorMatveyeva, N. V.-
dc.contributor.authorMcGuire, A. D.-
dc.contributor.authorMurray, D. F.-
dc.contributor.authorRazzhivin, V. Y.-
dc.contributor.authorSmith, B.-
dc.contributor.authorWalker, D. A.-
dc.contributor.authorAnderson, P. M.-
dc.contributor.authorAndreev, A. A.-
dc.contributor.authorBrubaker, L. B.-
dc.contributor.authorEdwards, M. E.-
dc.contributor.authorLozhkin, A. V.-
dc.date.accessioned2019-03-25T07:59:51Z-
dc.date.available2019-03-25T07:59:51Z-
dc.date.issued2003-
dc.identifier.citationJournal of Geophysical Research D: Atmospheres, 2003, v. 108, n. 19-
dc.identifier.issn0148-0227-
dc.identifier.urihttp://hdl.handle.net/10722/268499-
dc.description.abstractLarge variations in the composition, structure, and function of Arctic ecosystems are determined by climatic gradients, especially of growing-season warmth, soil moisture, and snow cover. A unified circumpolar classification recognizing five types of tundra was developed. The geographic distributions of vegetation types north of 55°N, including the position of the forest limit and the distributions of the tundra types, could be predicted from climatology using a small set of plant functional types embedded in the biogeochemistry-biogeography model BIOME4. Several palaeoclimate simulations for the last glacial maximum (LGM) and mid-Holocene were used to explore the possibility of simulating past vegetation patterns, which are independently known based on pollen data. The broad outlines of observed changes in vegetation were captured. LGM simulations showed the major reduction of forest, the great extension of graminoid and forb tundra, and the restriction of low- and high-shrub tundra (although not all models produced sufficiently dry conditions to mimic the full observed change). Mid-Holocene simulations reproduced the contrast between northward forest extension in western and central Siberia and stability of the forest limit in Beringia. Projection of the effect of a continued exponential increase in atmospheric CO2 concentration, based on a transient ocean-atmosphere simulation including sulfate aerosol effects, suggests a potential for larger changes in Arctic ecosystems during the 21st century than have occurred between mid-Holocene and present. Simulated physiological effects of the CO2 increase (to > 700 ppm) at high latitudes were slight compared with the effects of the change in climate.-
dc.languageeng-
dc.relation.ispartofJournal of Geophysical Research D: Atmospheres-
dc.subjectIce age-
dc.subjectBiome-
dc.subjectBiogeography-
dc.subjectVegetation modeling-
dc.subjectTundra-
dc.subjectMammoths-
dc.titleClimate change and Arctic ecosystems: 2. Modeling, paleodata-model comparisons, and future projections-
dc.typeArticle-
dc.description.naturelink_to_OA_fulltext-
dc.identifier.doi10.1029/2002JD002559-
dc.identifier.scopuseid_2-s2.0-0346758171-
dc.identifier.volume108-
dc.identifier.issue19-
dc.identifier.spagenull-
dc.identifier.epagenull-
dc.identifier.isiWOS:000185928300002-
dc.identifier.issnl0148-0227-

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