The importance of understanding annual and shorter-term temperature patterns and variation in the surface levels of polar soils for terrestrial biota

Ground temperatures in the top few centimetres of the soil profile are key in many biological processes yet remain very poorly documented, especially in the polar regions or over longer timescales. They can vary greatly seasonally and at various spatial scales across the often highly complex and het...

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Vydané v:	Polar biology Ročník 41; číslo 8; s. 1587 - 1605
Hlavní autori:	Convey, P., Coulson, S. J., Worland, M. R., Sjöblom, A.
Médium:	Journal Article
Jazyk:	English
Vydavateľské údaje:	Berlin/Heidelberg Springer Berlin Heidelberg 01.08.2018 Springer Springer Nature B.V
Predmet:	Air temperature Annual Biological activity Biology Biomedical and Life Sciences Biota Climate change Climate Research Comparative analysis Comparative studies Datasets Duration Ecology Ecosystems Freeze-thawing Global temperature changes Heterogeneity Klimatforskning Landscape Life Sciences Microbiology Microclimate Oceanography Original Paper Plant Sciences Polar environments Records Regions Soil Soil profiles Soil properties Soil temperature Soils Surface temperature Temperature Temperature effects Terrestrial ecosystems Thawing Trends Weather Zoology Arctic region Microbiota Plants Energy exchange Arctic Antarctic Terrestrial invertebrates
ISSN:	0722-4060, 1432-2056, 1432-2056
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Abstract	Ground temperatures in the top few centimetres of the soil profile are key in many biological processes yet remain very poorly documented, especially in the polar regions or over longer timescales. They can vary greatly seasonally and at various spatial scales across the often highly complex and heterogeneous polar landscapes. It is challenging and often impossible to extrapolate soil profile temperatures from meteorological air temperature records. Furthermore, despite the justifiably considerable profile given to contemporary large-scale climate change trends, with the exception of some sites on Greenland, few biological microclimate datasets exist that are of sufficient duration to allow robust linkage and comparison with these large-scale trends. However, it is also clear that the responses of the soil-associated biota of the polar regions to projected climate change cannot be adequately understood without improved knowledge of how landscape heterogeneity affects ground and sub-surface biological microclimates, and of descriptions of these microclimates and their patterns and trends at biologically relevant physical and temporal scales. To stimulate research and discussion in this field, we provide an overview of multi-annual temperature records from 20 High Arctic (Svalbard) and maritime Antarctic (Antarctic Peninsula and Scotia Arc) sites. We highlight important features in the datasets that are likely to have influence on biology in polar terrestrial ecosystems, including (a) summer ground and sub-surface temperatures vary much more than air temperatures; (b) winter ground temperatures are generally uncoupled from air temperatures; (c) the ground thawing period may be considerably shorter than that of positive air temperatures; (d) ground and air freeze–thaw patterns differ seasonally between Arctic and Antarctic; (e) rates of ground temperature change are generally low; (f) accumulated thermal sum in the ground usually greatly exceeds air cumulative degree days. The primary purpose of this article is to highlight the utility and biological relevance of such data, and to this end the full datasets are provided here to enable further analyses by the research community, and incorporation in future wider comparative studies.
AbstractList	Ground temperatures in the top few centimetres of the soil profile are key in many biological processes yet remain very poorly documented, especially in the polar regions or over longer timescales. They can vary greatly seasonally and at various spatial scales across the often highly complex and heterogeneous polar landscapes. It is challenging and often impossible to extrapolate soil profile temperatures from meteorological air temperature records. Furthermore, despite the justifiably considerable profile given to contemporary large-scale climate change trends, with the exception of some sites on Greenland, few biological microclimate datasets exist that are of sufficient duration to allow robust linkage and comparison with these large-scale trends. However, it is also clear that the responses of the soil-associated biota of the polar regions to projected climate change cannot be adequately understood without improved knowledge of how landscape heterogeneity affects ground and sub-surface biological microclimates, and of descriptions of these microclimates and their patterns and trends at biologically relevant physical and temporal scales. To stimulate research and discussion in this field, we provide an overview of multi-annual temperature records from 20 High Arctic (Svalbard) and maritime Antarctic (Antarctic Peninsula and Scotia Arc) sites. We highlight important features in the datasets that are likely to have influence on biology in polar terrestrial ecosystems, including (a) summer ground and sub-surface temperatures vary much more than air temperatures; (b) winter ground temperatures are generally uncoupled from air temperatures; (c) the ground thawing period may be considerably shorter than that of positive air temperatures; (d) ground and air freeze-thaw patterns differ seasonally between Arctic and Antarctic; (e) rates of ground temperature change are generally low; (f) accumulated thermal sum in the ground usually greatly exceeds air cumulative degree days. The primary purpose of this article is to highlight the utility and biological relevance of such data, and to this end the full datasets are provided here to enable further analyses by the research community, and incorporation in future wider comparative studies.
Audience	Academic
Author	Coulson, S. J. Sjöblom, A. Worland, M. R. Convey, P.
Author_xml	– sequence: 1 givenname: P. orcidid: 0000-0001-8497-9903 surname: Convey fullname: Convey, P. email: pcon@bas.ac.uk organization: British Antarctic Survey, NERC, High Cross – sequence: 2 givenname: S. J. surname: Coulson fullname: Coulson, S. J. organization: Department of Arctic Biology, University Centre in Svalbard, ArtDatabanken, The Swedish Species Information Centre, Swedish University of Agricultural Sciences – sequence: 3 givenname: M. R. surname: Worland fullname: Worland, M. R. organization: British Antarctic Survey, NERC, High Cross – sequence: 4 givenname: A. surname: Sjöblom fullname: Sjöblom, A. organization: Department of Earth Sciences, Uppsala University
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Copyright	Springer-Verlag GmbH Germany, part of Springer Nature 2018 COPYRIGHT 2018 Springer Polar Biology is a copyright of Springer, (2018). All Rights Reserved.
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SubjectTerms	Air temperature Annual Biological activity Biology Biomedical and Life Sciences Biota Climate change Climate Research Comparative analysis Comparative studies Datasets Duration Ecology Ecosystems Freeze-thawing Global temperature changes Heterogeneity Klimatforskning Landscape Life Sciences Microbiology Microclimate Oceanography Original Paper Plant Sciences Polar environments Records Regions Soil Soil profiles Soil properties Soil temperature Soils Surface temperature Temperature Temperature effects Terrestrial ecosystems Thawing Trends Weather Zoology
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Title	The importance of understanding annual and shorter-term temperature patterns and variation in the surface levels of polar soils for terrestrial biota
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