Abstract
IntroductionCurrent glacier retreat makes vast mountain ranges available for vegetation establishment and growth. As a result, carbon (C) is accumulated in the soil, in a negative feedback to climate change. Little is known about the effective C budget of these new ecosystems and how the presence of different vegetation communities influences CO2 fluxes.MethodsOn the Matsch glacier forefield (Alps, Italy) we measured over two growing seasons the Net Ecosystem Exchange (NEE) of a typical grassland, dominated by the C3 Festuca halleri All., and a community dominated by the CAM rosettes Sempervivum montanum L. Using transparent and opaque chambers, with air temperature as the driver, we partitioned NEE to calculate Ecosystem Respiration (Reco) and Gross Ecosystem Exchange (GEE). In addition, soil and vegetation samples were collected from the same sites to estimate the Net Ecosystem Carbon Balance (NECB).ResultsThe two communities showed contrasting GEE but similar Reco patterns, and as a result they were significantly different in NEE during the period measured. The grassland acted as a C sink, with a total cumulated value of -46.4±35.5 g C m-2 NEE, while the plots dominated by the CAM rosettes acted as a source, with 31.9±22.4 g C m-2. In spite of the different NEE, soil analysis did not reveal significant differences in carbon accumulation of the two plant communities (1770±130 for F. halleri and 2080±230 g C m-2 for S. montanum), suggesting that processes often neglected, like lateral flows and winter respiration, can have a similar relevance as NEE in the determination of the Net Ecosystem Carbon Balance.
Highlights
Current glacier retreat makes vast mountain ranges available for vegetation establishment and growth
The grassland acted as a C sink, with a total cumulated value of -46.4±35.5 g C m-2 Net Ecosystem Exchange (NEE), while the plots dominated by the CAM rosettes acted as a source, with 31.9±22.4 g C m-2
To analyse C flux data in Sempervivum plots and their relation to the environmental variables, we considered the four phases of CAM plants as described by Osmond [48]: phase 1 at night, carboxylation of atmospheric CO2 occurs through phosphoenolpyruvate (PEP) carboxylase and storage of C through the production of malic acid; phase 2 in the morning, carboxylation of atmospheric CO2 occurs through both PEP and ribulose bisphosphate carboxylase oxygenase (Rubisco); phase 3 during the central hours of the day, the decarboxylation of malic acid and the consequent re-fixation of C through Rubisco carboxylase occur; phase 4 during the afternoon, fixation of atmospheric CO2 occurs through Rubisco carboxylase
Summary
Current glacier retreat makes vast mountain ranges available for vegetation establishment and growth. Little is known about the effective C budget of these new ecosystems and how the presence of different vegetation communities influences CO2 fluxes
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