| Abstract | In alpine tundra the influence of snow-cover duration (SCD) and pedoclimatic conditions on soil nutrient forms during the growing season has received little attention. The hypothesis that SCD influences the soil temperature, which in turn can affect the annual changes in topsoil nitrogen (N) and carbon (C) forms, was tested for five growing seasons at three study sites in the alpine tundra of the NW Italian Alps. Among the pedoclimatic conditions studied (soil temperature, soil moisture, and number of freeze/thaw cycles), the mean soil temperature of the growing season was inversely correlated with the SCD (p < 0.01), which ranged from 216 to 272 days. Independently from the soil characteristics (e.g., degree of evolution), the microbial carbon (C micr) of the growing season was inversely correlated with the SCD and the mean soil temperature of the snow-covered season, suggesting the consumption of soil resources made by the C micr under the snowpack. During the growing season ammonium (N-NH 4 +), dissolved organic carbon (DOC), and C micr were positively correlated with soil temperature and moisture. Path analysis shows that the interannual variability of topsoil N and C forms was significantly controlled by the pedoclimatic conditions recorded in both the snow-covered and the subsequent growing seasons, which in turn were influenced by SCD. Therefore, SCD played a fundamental role in terms of pedoclimatic conditions during the growing season, contributing to explaining the interannual variability of soil N and C forms, and may be a key factor for predicting the nutrient cycling in alpine tundra in the context of a changing climate. |
| Text | 372982 2017 10.1657/AAAR0016 037 Scopus 2 s2.0 85019770331 ISI Web of Science WOS 000402283000004 soil nutrient microbial carbon nitrate Interannual variability of soil n and c forms in response to snow cover duration and Pedoclimatic conditions in alpine tundra, northwest Italy Magnani A.; Viglietti D.; Godone D.; Williams M.W.; Balestrini R.; Freppaz M. Department of Agricultural, Forest and Food Sciences, University of Torino, Largo Paolo Braccini 2, Grugliasco TO , 10095, , Italy; Research Center on Natural Risk in Mountain and Hilly Environments, NatRisk, University of Torino, Largo Paolo Braccini 2, Grugliasco TO , 10095, , Italy; Geohazard Monitoring Group, CNR IRPI, Strada delle Cacce 73, Torino, 10135, , Italy; Department of Geography and Institute of Arctic and Alpine Research, University of Colorado, Boulder, CO, 80309 0450, , United States; Water Research Institute IRSA CNR , Via del Mulino 19, Brugherio MB , 20861, , Italy In alpine tundra the influence of snow cover duration SCD and pedoclimatic conditions on soil nutrient forms during the growing season has received little attention. The hypothesis that SCD influences the soil temperature, which in turn can affect the annual changes in topsoil nitrogen N and carbon C forms, was tested for five growing seasons at three study sites in the alpine tundra of the NW Italian Alps. Among the pedoclimatic conditions studied soil temperature, soil moisture, and number of freeze/thaw cycles , the mean soil temperature of the growing season was inversely correlated with the SCD p < 0.01 , which ranged from 216 to 272 days. Independently from the soil characteristics e.g., degree of evolution , the microbial carbon C micr of the growing season was inversely correlated with the SCD and the mean soil temperature of the snow covered season, suggesting the consumption of soil resources made by the C micr under the snowpack. During the growing season ammonium N NH 4 , dissolved organic carbon DOC , and C micr were positively correlated with soil temperature and moisture. Path analysis shows that the interannual variability of topsoil N and C forms was significantly controlled by the pedoclimatic conditions recorded in both the snow covered and the subsequent growing seasons, which in turn were influenced by SCD. Therefore, SCD played a fundamental role in terms of pedoclimatic conditions during the growing season, contributing to explaining the interannual variability of soil N and C forms, and may be a key factor for predicting the nutrient cycling in alpine tundra in the context of a changing climate. 49 Published version http //www.scopus.com/record/display.url eid=2 s2.0 85019770331 origin=inward Articolo in rivista Institute of Arctic and Alpine Research, University of Colorado at Boulder, 1523 0430 Arctic, antarctic, and alpine research Arctic, antarctic, and alpine research Arct. antarct. alp. res. Arctic, antarctic, and alpine research. danilofrancescostefano.godone GODONE DANILO FRANCESCO STEFANO raffaella.balestrini BALESTRINI RAFFAELLA |
