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@article{1796286, author = {Horsák, Michal and Horsáková, Veronika and Polášek, Marek and Coufal, Radovan and Hájková, Petra and Hájek, Michal}, article_location = {Hoboken}, article_number = {7}, doi = {http://dx.doi.org/10.1002/hyp.14293}, keywords = {climate change; soil thermal buffering; spring mire; temperature datalogger; water saturation; within-site variation}, language = {eng}, issn = {0885-6087}, journal = {Hydrological Processes}, title = {Spring water table depth mediates within-site variation of soil temperature in groundwater-fed mires}, url = {https://doi.org/10.1002/hyp.14293}, volume = {35}, year = {2021} }
TY - JOUR ID - 1796286 AU - Horsák, Michal - Horsáková, Veronika - Polášek, Marek - Coufal, Radovan - Hájková, Petra - Hájek, Michal PY - 2021 TI - Spring water table depth mediates within-site variation of soil temperature in groundwater-fed mires JF - Hydrological Processes VL - 35 IS - 7 SP - "e14293" EP - "e14293" PB - John Wiley & Sons SN - 08856087 KW - climate change KW - soil thermal buffering KW - spring mire KW - temperature datalogger KW - water saturation KW - within-site variation UR - https://doi.org/10.1002/hyp.14293 N2 - Groundwater-dependent ecosystems represent globally rare edaphic islands of scattered distribution, often forming areas of regionally unique environmental conditions. A stable groundwater supply is a key parameter defining their ecological specificity, promoting also soil thermal buffering. Still, a limited number of studies dealt with the importance of water temperature in mire ecosystems and virtually no data exist on within-site variation in the temperature buffer effect. Three temperature dataloggers, placed in patches potentially differing in groundwater supply, were installed in each of 19 Western Carpathian spring mire sites from May 2019 to July 2020. Spring source plots statistically differed in water temperature parameters from the plots located towards the spring mire margin, which did not significantly differ from one another. At the majority of sites, the temperature values changed gradually from spring source to mire margins, fitting the pattern expected in the groundwater temperature buffering scenario. Dataloggers placed in the spring sources were the most distinctive from the others in thermal buffering parameters in conditional principal component analysis. The difference between the spring source and its margin was on average 3.25 degrees C for 95th percentile of the recorded water temperature data points (i.e. warm extremes) and 1.91 degrees C for 5th percentile (i.e. cold extremes). This suggests that if the temperature at spring source area is considered, thermal buffering within a site may mitigate mainly warm extremes. Thus, our data may provide an important baseline for predictions of possibly upcoming changes in spring mire hydrology caused by climate change. Both warming and precipitation decrease can give rise to the loss or substantial reduction of buffering effect if the contrasting parameters now recorded at the central part shift to those found towards the margins of groundwater-fed areas. ER -
HORSÁK, Michal, Veronika HORSÁKOVÁ, Marek POLÁŠEK, Radovan COUFAL, Petra HÁJKOVÁ and Michal HÁJEK. Spring water table depth mediates within-site variation of soil temperature in groundwater-fed mires. \textit{Hydrological Processes}. Hoboken: John Wiley \&{} Sons, 2021, vol.~35, No~7, p.~''e14293'', 11 pp. ISSN~0885-6087. Available from: https://dx.doi.org/10.1002/hyp.14293.
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