Your search keyword '"JANSSENS, IVAN. A."' showing total 3 results

1. Carbon–nitrogen interactions in European forests and semi-natural vegetation – Part 2: Untangling climatic, edaphic, management and nitrogen deposition effects on carbon sequestration potentials.

Author

Flechard, Chris R., van Oijen, Marcel, Cameron, David R., de Vries, Wim, Ibrom, Andreas, Buchmann, Nina, Dise, Nancy B., Janssens, Ivan A., Neirynck, Johan, Montagnani, Leonardo, Varlagin, Andrej, Loustau, Denis, Legout, Arnaud, Ziemblińska, Klaudia, Aubinet, Marc, Aurela, Mika, Chojnicki, Bogdan H., Drewer, Julia, Eugster, Werner, and Francez, André-Jean

Subjects

CARBON sequestration, FOREST plants, ATMOSPHERIC nitrogen, ATMOSPHERIC deposition, CONFOUNDING variables, PRIMARY productivity (Biology), FOREST soils

Abstract

The effects of atmospheric nitrogen deposition (Ndep) on carbon (C) sequestration in forests have often been assessed by relating differences in productivity to spatial variations of Ndep across a large geographic domain. These correlations generally suffer from covariation of other confounding variables related to climate and other growth-limiting factors, as well as large uncertainties in total (dry + wet) reactive nitrogen (Nr) deposition. We propose a methodology for untangling the effects of Ndep from those of meteorological variables, soil water retention capacity and stand age, using a mechanistic forest growth model in combination with eddy covariance CO2 exchange fluxes from a Europe-wide network of 22 forest flux towers. Total Nr deposition rates were estimated from local measurements as far as possible. The forest data were compared with data from natural or semi-natural, non-woody vegetation sites. The response of forest net ecosystem productivity to nitrogen deposition (dNEP/dNdep) was estimated after accounting for the effects on gross primary productivity (GPP) of the co-correlates by means of a meta-modelling standardization procedure, which resulted in a reduction by a factor of about 2 of the uncorrected, apparent dGPP/dNdep value. This model-enhanced analysis of the C and Ndep flux observations at the scale of the European network suggests a mean overall dNEP/dNdep response of forest lifetime C sequestration to Ndep of the order of 40–50 g C per g N, which is slightly larger but not significantly different from the range of estimates published in the most recent reviews. Importantly, patterns of gross primary and net ecosystem productivity versus Ndep were non-linear, with no further growth responses at high Ndep levels (Ndep > 2.5–3 g N m -2 yr -1) but accompanied by increasingly large ecosystem N losses by leaching and gaseous emissions. The reduced increase in productivity per unit N deposited at high Ndep levels implies that the forecast increased Nr emissions and increased Ndep levels in large areas of Asia may not positively impact the continent's forest CO2 sink. The large level of unexplained variability in observed carbon sequestration efficiency (CSE) across sites further adds to the uncertainty in the dC/dN response. [ABSTRACT FROM AUTHOR]

Published

2020

2. Carbon / nitrogen interactions in European forests and semi-natural vegetation. Part II: Untangling climatic, edaphic, management and nitrogen deposition effects on carbon sequestration potentials.

Author

Flechard, Chris R., van Oijen, Marcel, Cameron, David R., de Vries, Wim, Ibrom, Andreas, Buchmann, Nina, Dise, Nancy B., Janssens, Ivan A., Neirynck, Johan, Montagnani, Leonardo, Varlagin, Andrej, Loustau, Denis, Legout, Arnaud, Ziemblińska, Klaudia, Aubinet, Marc, Aurela, Mika, Chojnicki, Bogdan H., Drewer, Julia, Eugster, Werner, and Francez, André-Jean

Subjects

FOREST soils, CARBON sequestration, CARBON sequestration in forests, FOREST plants, ATMOSPHERIC nitrogen, PRIMARY productivity (Biology), ATMOSPHERIC deposition

Abstract

The effects of atmospheric nitrogen deposition (Ndep) on carbon (C) sequestration in forests have often been assessed by relating differences in productivity to spatial variations of Ndep across a large geographic domain. These correlations generally suffer from covariation of other confounding variables related to climate and other growth-limiting factors, as well as large uncertainties in total (dry + wet) reactive nitrogen (Nr) deposition. We propose a methodology for untangling the effects of Ndep from those of meteorological variables, soil water retention capacity and stand age, using a mechanistic forest growth model in combination with eddy covariance CO2 exchange fluxes from a Europe-wide network of forest flux towers. Total Nr deposition rates were estimated from local measurements as far as possible. The forest data were compared with data from natural or semi-natural, non-woody vegetation sites. The carbon sequestration response of forests to nitrogen deposition (dC / dN) was estimated after accounting for the effects of the co-correlates by means of a meta-modelling standardization procedure, which resulted in a reduction by a factor of about 2 of the uncorrected, apparent dC / dN value. This model-enhanced analysis of the C and Ndep flux observations at the scale of the European network suggests a mean overall dC / dN response of forest lifetime C sequestration to Ndep of the order of 40–50 g (C) g−1 (N), which is slightly larger but not significantly different from the range of estimates published in the most recent reviews. Importantly, patterns of gross primary and net ecosystem productivity versus Ndep were non-linear, with no further responses at high Ndep levels (Ndep > 2.5–3 g (N) m−2 yr−1) partly due to large ecosystem N losses by leaching and gaseous emissions. The reduced increase in productivity per unit N deposited at high Ndep levels implies that the forecast increased Nr emissions and increased Ndep levels in large areas of Asia may not positively impact the continent's forest CO2 sink. The large level of unexplained variability in observed carbon sequestration efficiency (CSE) across sites further adds to the uncertainty in the dC / dN response [ABSTRACT FROM AUTHOR]

Published

2019

3. Global forest carbon uptake due to nitrogen and phosphorus deposition from 1850 to 2100.

Author

Wang, Rong, Goll, Daniel, Balkanski, Yves, Hauglustaine, Didier, Boucher, Olivier, Ciais, Philippe, Janssens, Ivan, Penuelas, Josep, Guenet, Bertrand, Sardans, Jordi, Bopp, Laurent, Vuichard, Nicolas, Zhou, Feng, Li, Bengang, Piao, Shilong, Peng, Shushi, Huang, Ye, and Tao, Shu

Subjects

AEROSOLS, ATMOSPHERIC deposition, CARBON cycle, STOICHIOMETRY, FORESTS & forestry

Abstract

Spatial patterns and temporal trends of nitrogen (N) and phosphorus (P) deposition are important for quantifying their impact on forest carbon (C) uptake. In a first step, we modeled historical and future change in the global distributions of the atmospheric deposition of N and P from the dry and wet deposition of aerosols and gases containing N and P. Future projections were compared between two scenarios with contrasting aerosol emissions. Modeled fields of N and P deposition and P concentration were evaluated using globally distributed in situ measurements. N deposition peaked around 1990 in European forests and around 2010 in East Asian forests, and both increased sevenfold relative to 1850. P deposition peaked around 2010 in South Asian forests and increased 3.5-fold relative to 1850. In a second step, we estimated the change in C storage in forests due to the fertilization by deposited N and P (∆Cν dep), based on the retention of deposited nutrients, their allocation within plants, and C:N and C:P stoichiometry. ∆Cν dep for 1997-2013 was estimated to be 0.27 ± 0.13 Pg C year−1 from N and 0.054 ± 0.10 Pg C year−1 from P, contributing 9% and 2% of the terrestrial C sink, respectively. Sensitivity tests show that uncertainty of ∆Cν dep was larger from P than from N, mainly due to uncertainty in the fraction of deposited P that is fixed by soil. ∆ CP dep was exceeded by ∆ CN dep over 1960-2007 in a large area of East Asian and West European forests due to a faster growth in N deposition than P. Our results suggest a significant contribution of anthropogenic P deposition to C storage, and additional sources of N are needed to support C storage by P in some Asian tropical forests where the deposition rate increased even faster for P than for N. [ABSTRACT FROM AUTHOR]

Published

2017