Your search keyword '"Chen, Anping"' showing total 4 results

1. Ecological and political costs of river diversion.

Author

Chen, Anping and Changdu Chen

Subjects

*LETTERS to the editor, *AGRICULTURE

Abstract

Presents the letter to the editor, regarding the article "Agriculture of the Future," published in a previous issue of the periodical.

Published

2004

2. A two-fold increase of carbon cycle sensitivity to tropical temperature variations.

Author

Wang, Xuhui, Piao, Shilong, Ciais, Philippe, Friedlingstein, Pierre, Myneni, Ranga B., Cox, Peter, Heimann, Martin, Miller, John, Peng, Shushi, Wang, Tao, Yang, Hui, and Chen, Anping

Subjects

*CARBON dioxide, *CARBON cycle, *BIOGEOCHEMICAL cycles, *CARBON fixation, *CLIMATE change

Abstract

Earth system models project that the tropical land carbon sink will decrease in size in response to an increase in warming and drought during this century, probably causing a positive climate feedback. But available data are too limited at present to test the predicted changes in the tropical carbon balance in response to climate change. Long-term atmospheric carbon dioxide data provide a global record that integrates the interannual variability of the global carbon balance. Multiple lines of evidence demonstrate that most of this variability originates in the terrestrial biosphere. In particular, the year-to-year variations in the atmospheric carbon dioxide growth rate (CGR) are thought to be the result of fluctuations in the carbon fluxes of tropical land areas. Recently, the response of CGR to tropical climate interannual variability was used to put a constraint on the sensitivity of tropical land carbon to climate change. Here we use the long-term CGR record from Mauna Loa and the South Pole to show that the sensitivity of CGR to tropical temperature interannual variability has increased by a factor of 1.9 ± 0.3 in the past five decades. We find that this sensitivity was greater when tropical land regions experienced drier conditions. This suggests that the sensitivity of CGR to interannual temperature variations is regulated by moisture conditions, even though the direct correlation between CGR and tropical precipitation is weak. We also find that present terrestrial carbon cycle models do not capture the observed enhancement in CGR sensitivity in the past five decades. More realistic model predictions of future carbon cycle and climate feedbacks require a better understanding of the processes driving the response of tropical ecosystems to drought and warming. [ABSTRACT FROM AUTHOR]

Published

2014

3. Asymmetric effects of daytime and night-time warming on Northern Hemisphere vegetation.

Author

Peng, Shushi, Piao, Shilong, Ciais, Philippe, Myneni, Ranga B., Chen, Anping, Chevallier, Frédéric, Dolman, Albertus J., Janssens, Ivan A., Peñuelas, Josep, Zhang, Gengxin, Vicca, Sara, Wan, Shiqiang, Wang, Shiping, and Zeng, Hui

Subjects

*EFFECT of temperature on plants, *PHOTOSYNTHESIS, *PLANT assimilation, *CARBON content of plants, *PLANT ecology, *ATMOSPHERIC carbon dioxide

Abstract

Temperature data over the past five decades show faster warming of the global land surface during the night than during the day. This asymmetric warming is expected to affect carbon assimilation and consumption in plants, because photosynthesis in most plants occurs during daytime and is more sensitive to the maximum daily temperature, Tmax, whereas plant respiration occurs throughout the day and is therefore influenced by both Tmax and the minimum daily temperature, Tmin. Most studies of the response of terrestrial ecosystems to climate warming, however, ignore this asymmetric forcing effect on vegetation growth and carbon dioxide (CO2) fluxes. Here we analyse the interannual covariations of the satellite-derived normalized difference vegetation index (NDVI, an indicator of vegetation greenness) with Tmax and Tmin over the Northern Hemisphere. After removing the correlation between Tmax and Tmin, we find that the partial correlation between Tmax and NDVI is positive in most wet and cool ecosystems over boreal regions, but negative in dry temperate regions. In contrast, the partial correlation between Tmin and NDVI is negative in boreal regions, and exhibits a more complex behaviour in dry temperate regions. We detect similar patterns in terrestrial net CO2 exchange maps obtained from a global atmospheric inversion model. Additional analysis of the long-term atmospheric CO2 concentration record of the station Point Barrow in Alaska suggests that the peak-to-peak amplitude of CO2 increased by 23 ± 11% for a +1 °C anomaly in Tmax from May to September over lands north of 51° N, but decreased by 28 ± 14% for a +1 °C anomaly in Tmin. These lines of evidence suggest that asymmetric diurnal warming, a process that is currently not taken into account in many global carbon cycle models, leads to a divergent response of Northern Hemisphere vegetation growth and carbon sequestration to rising temperatures. [ABSTRACT FROM AUTHOR]

Published

2013

4. Net carbon dioxide losses of northern ecosystems in response to autumn warming.

Author

Piao, Shilong, Ciais, Philippe, Friedlingstein, Pierre, Peylin, Philippe, Reichstein, Markus, Luyssaert, Sebastiaan, Margolis, Hank, Fang, Jingyun, Barr, Alan, Chen, Anping, Grelle, Achim, Hollinger, David Y., Laurila, Tuomas, Lindroth, Anders, Richardson, Andrew D., and Vesala, Timo

Subjects

*CLIMATE change, *CARBON dioxide & the environment, *ECOSYSTEM health, *ECOLOGICAL disturbances, *CLIMATOLOGY, *BIOSPHERE

Abstract

The carbon balance of terrestrial ecosystems is particularly sensitive to climatic changes in autumn and spring, with spring and autumn temperatures over northern latitudes having risen by about 1.1 °C and 0.8 °C, respectively, over the past two decades. A simultaneous greening trend has also been observed, characterized by a longer growing season and greater photosynthetic activity. These observations have led to speculation that spring and autumn warming could enhance carbon sequestration and extend the period of net carbon uptake in the future. Here we analyse interannual variations in atmospheric carbon dioxide concentration data and ecosystem carbon dioxide fluxes. We find that atmospheric records from the past 20 years show a trend towards an earlier autumn-to-winter carbon dioxide build-up, suggesting a shorter net carbon uptake period. This trend cannot be explained by changes in atmospheric transport alone and, together with the ecosystem flux data, suggest increasing carbon losses in autumn. We use a process-based terrestrial biosphere model and satellite vegetation greenness index observations to investigate further the observed seasonal response of northern ecosystems to autumnal warming. We find that both photosynthesis and respiration increase during autumn warming, but the increase in respiration is greater. In contrast, warming increases photosynthesis more than respiration in spring. Our simulations and observations indicate that northern terrestrial ecosystems may currently lose carbon dioxide in response to autumn warming, with a sensitivity of about 0.2 PgC °C-1, offsetting 90% of the increased carbon dioxide uptake during spring. If future autumn warming occurs at a faster rate than in spring, the ability of northern ecosystems to sequester carbon may be diminished earlier than previously suggested. [ABSTRACT FROM AUTHOR]

Published

2008