A representation of the phosphorus cycle for ORCHIDEE (revision 4520)

Goll, Daniel S.; Vuichard, Nicolas; Maignan, Fabienne; Jornet-Puig, Albert; Sardans, Jordi; Violette, Aurélie; Peng, Shushi; Sun, Yan; Kvakić, Marko; Guimberteau, Matthieu; Guenet, Bertrand; Zaehle, Sönke; Peñuelas, Josep; Janssens, Ivan A.; Ciais, Philippe

doi:10.5194/gmd-10-3745-2017

Cited by 138 publications

(126 citation statements)

References 100 publications

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“…However, recent work has suggested an increasing role of nutrients limiting the productivity of ecosystems; both data and modeling efforts have shown that carbon dioxide (CO 2 ) uptake by terrestrial ecosystems strongly depends on nutrient availability (Bonan 2008, Peñuelas et al 2013, Fernandez-Martinez et al 2014. This has instigated the implementation of the effects of nutrient stocks and cycling in land-surface models (Wang et al 2010, Zaehle and Friend 2010, Goll et al 2012, 2017 and stressed the need for a profound and mechanistic understanding of nutrient cycling effects on the C cycle. Nitrogen (N) is of particular interest, being one of the important macronutrients to sustain plant life.…”

Section: Introductionmentioning

confidence: 99%

Contrasting nitrogen fluxes in African tropical forests of the Congo Basin

Bauters

Verbeeck

Rütting

et al. 2019

Ecological Monographs

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The observation of high losses of bioavailable nitrogen (N) and N richness in tropical forests is paradoxical with an apparent lack of N input. Hence, the current concept asserts that biological nitrogen fixation (BNF) must be a major N input for tropical forests. However, well‐characterized N cycles are rare and geographically biased; organic N compounds are often neglected and soil gross N cycling is not well quantified. We conducted comprehensive N input and output measurements in four tropical forest types of the Congo Basin with contrasting biotic (mycorrhizal association) and abiotic (lowland–highland) environments. In 12 standardized setups, we monitored N deposition, throughfall, litterfall, leaching, and export during one hydrological year and completed this empirical N budget with nitrous oxide (N2O) flux measurement campaigns in both wet and dry season and in situ gross soil N transformations using 15N‐tracing and numerical modeling. We found that all forests showed a very tight soil N cycle, with gross mineralization to immobilization ratios (M/I) close to 1 and relatively low gross nitrification to mineralization ratios (N/M). This was in line with the observation of dissolved organic nitrogen (DON) dominating N losses for the most abundant, arbuscular mycorrhizal associated, lowland forest type, but in contrast with high losses of dissolved inorganic nitrogen (DIN) in all other forest types. Altogether, our observations show that different forest types in central Africa exhibit N fluxes of contrasting magnitudes and N‐species composition. In contrast to many Neotropical forests, our estimated N budgets of central African forests are imbalanced by a higher N input than output, with organic N contributing significantly to the input‐output balance. This suggests that important other losses that are unaccounted for (e.g., NOx and N2 as well as particulate N) might play a major role in the N cycle of mature African tropical forests.

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Section: Introductionmentioning

confidence: 99%

Contrasting nitrogen fluxes in African tropical forests of the Congo Basin

Bauters

Verbeeck

Rütting

et al. 2019

Ecological Monographs

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“…Global ecosystem models are progressively incorporating dynamic N and P cycles to test their control on the global C balance (Buendía et al, 2014;Goll et al, 2012Goll et al, , 2017Yang et al, 2014). The land surface model CABLE considers C, N, and P dynamics and has previously been employed to estimate the control of N and P limitation on the historical and future global C balance (Y.-P. Wang et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

Nitrogen Deposition Maintains a Positive Effect on Terrestrial Carbon Sequestration in the 21st Century Despite Growing Phosphorus Limitation at Regional Scales

Fleischer

Dolman

Molen

et al. 2019

Global Biogeochemical Cycles

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Nitrogen (N) and phosphorus (P) are two dominant nutrients regulating the productivity of most terrestrial ecosystems. The growing imbalance of anthropogenic N and P inputs into the future is estimated to exacerbate P limitation on land and limit the land carbon (C) sink, so that we hypothesized that P limitation will increasingly reduce C sequestered per unit N deposited into the future. Using a global land surface model (CABLE), we simulated the effects of increased N deposition with and without P limitation on land C uptake and the fate of deposited N on land from 1901 to 2100. Contrary to our hypothesis, we found that N deposition continued to induce land C sequestration into the future, contributing to 15% of future C sequestration as opposed to 6% over the historical period. P limitation reduced the future land C uptake per unit N deposited only moderately at the global scale but P limitation increasingly caused N deposition to have net negative effects on the land C balance in the temperate zone. P limitation further increased the fraction of deposited N that is lost via leaching to aquatic ecosystems, globally from 38.5% over the historical period to 53% into the future, and up to 75% in tropical ecosystems. Our results suggest continued N demand for plant productivity but also indicate growing adverse N deposition effects in the future biosphere, not fully accounted for in global models, emphasizing the urgent need to elaborate on model representations of N and P dynamics.

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“…At all three sites, nutrient availability is suboptimal when computed prognostically, this is indicated by leaf carbon:nitrogen:phosphorus ratios of 744:30:1, 1264:38:1, and 983:36:1 for BR‐Ma2, BR‐Sa1, and BR‐Sa3, respectively, which are elevated compared to the optimal ratio in ORCHIDEE of 267:17:1 (Goll et al, ). Furthermore, the nitrogen addition experiment (supporting information Text S3) and the elevated leaf nitrogen:phosphorus ratios indicate that nitrogen availability is not limiting plant productivity at all sites.…”

Section: Resultsmentioning

confidence: 99%

“…It has a detailed representation of root phosphorus uptake and accounts for root zone depletion of phosphorus as a function of root phosphorus uptake and phosphate ions diffusion controlled transport from the soil pores to the root surface. The major interactions between water and phosphorus cycling (Figure ) in ORCHIDEE are (1) the positive dependence of phosphate mobility on soil moisture (Equation 23 in Goll et al, ), which affects the uptake of phosphate by roots (Equation 4 in Goll et al, ) and its availability for plant growth, (2) the positive dependence of microbial mineralization on soil moisture (Section 2.1.3 in Goll et al, ), (3) the direct dependence of plant growth on plant internal phosphorus availability (Equation 13 in Goll et al, ), and (4) the indirect dependence of the photosynthetic capacity (maximum carboxylation rate) on leaf phosphorus. The latter is a consequence of constraints on the elasticity of the leaf nitrogen:phosphorus ratio (Equation 11 in Goll et al, ).…”

Section: Methodsmentioning

confidence: 99%

“…We exchanged the original formulation of phosphorus sorption, which assumes a fixed fraction of labile phosphorus being dissolved in soil solution (Goll et al, ) with a more realistic Freundlich Isotherm, which is parameterized based on a compilation of isotopic dilution data ( n = 379; Achat et al, ; Kvakić et al, ). Three different soil classes are distinguished in respect to sorption dynamics, namely, Oxisols, Molisols, and “others.” Details are given in supporting information Text S1.…”

Section: Methodsmentioning

confidence: 99%

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Low Phosphorus Availability Decreases Susceptibility of Tropical Primary Productivity to Droughts

Goll

Joetzjer

Huang

et al. 2018

Geophysical Research Letters

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Large uncertainties in the susceptibility of tropical forest productivity to precipitation changes hamper climate change projection. Interactions between the availabilities of water and phosphorus could theoretically either increase or decrease the susceptibility of tropical gas exchange to variation of precipitation. The inclusion of phosphorus‐water interactions in a land surface model reduces the coefficient of variance, a measure of variability, of biweekly gross primary productivity by a factor of 1.5–2.3 at three tropical forest sites in Brazil, bringing it closer to estimates from eddy covariance measurements and remote sensing. Soil drought conditions are attenuated due to 8–30% lower water consumption during wet periods in presence of phosphorus limitation. When soils are dry, plant phosphorus acquisition is impaired by reduced ion mobility, despite an increase in net phosphorus mineralization. We conclude that water‐phosphorus interactions cannot be omitted in analysis of the resilience of tropical ecosystems to precipitation changes.

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A representation of the phosphorus cycle for ORCHIDEE (revision 4520)

Cited by 138 publications

References 100 publications

Contrasting nitrogen fluxes in African tropical forests of the Congo Basin

Contrasting nitrogen fluxes in African tropical forests of the Congo Basin

Nitrogen Deposition Maintains a Positive Effect on Terrestrial Carbon Sequestration in the 21st Century Despite Growing Phosphorus Limitation at Regional Scales

Low Phosphorus Availability Decreases Susceptibility of Tropical Primary Productivity to Droughts

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