Your search keyword '"Renchon, Alexandre A."' showing total 1 results

1. Upside-down fluxes Down Under: CO2 net sink in winter and net source in summer in a temperate evergreen broadleaf forest.

Author

Renchon, Alexandre A., Griebel, Anne, Williams, Christopher A., Medlyn, Belinda, Duursma, Remko A., Barton, Craig V. M., Maier, Chelsea, Boer, Matthias M., Isaac, Peter, Tissue, David, Resco de Dios, Victor, and Pendall, Elise

Subjects

GRISELINIA littoralis, FOREST dynamics, ATMOSPHERIC carbon dioxide, METEOROLOGICAL precipitation, EUCALYPTUS

Abstract

Predicting the seasonal dynamics of ecosystem carbon fluxes is challenging in broadleaved evergreen forests because of their moderate climates and subtle changes in canopy phenology. We assessed the climatic and biotic drivers of the seasonality of net ecosystem-atmosphere CO2 exchange (NEE) of a eucalyptus-dominated forest near Sydney, Australia, using the eddy covariance method. The climate is characterized by a mean annual precipitation of 800 mm and a mean annual temperature of 18 °C, hot summers and mild winters, with highly variable precipitation. In the three-year study, the ecosystem was a small sink in 2014 (54 g C m-2 y-1), a stronger sink in 2015 (183 g C m-2 y-1) and even stronger sink in 2016 (337 g C m-2 y-1), but these variations were not related to precipitation. Daily net C uptake was always detected during the cooler, drier winter months (June through August), while net C loss occurred during the warmer, wetter summer months (December through February). Gross primary productivity (GPP) seasonality was low, despite longer days with higher light intensity in summer, because vapour pressure deficit (D) and air temperature (Ta) restricted surface conductance during summer while winter temperatures were still high enough to support photosynthesis. Maximum GPP during ideal environmental conditions was correlated with canopy leaf area index (LAI) (r² = 0.24), which increased rapidly after mid-summer rainfall events. Ecosystem respiration (ER) was highest during summer in wet soils and lowest during winter months. ER had larger seasonal amplitude compared to GPP, and therefore drove the seasonal variation of NEE. Because summer carbon uptake may become increasingly limited by atmospheric drought and high temperature, and ecosystem respiration could be enhanced by rising temperature, our results suggest the potential for large-scale seasonal shifts in NEE in sclerophyll vegetation under climate change. [ABSTRACT FROM AUTHOR]

Published

2018