Systematic assessment of terrestrial biogeochemistry in coupled climate–carbon models

Randerson, James T.; Hoffman, Forrest M.; Thornton, P. E.; Mahowald, N. M.; Lindsay, Keith; Lee, Yen-Huei; Nevison, C. D.; Doney, Scott C.; Bonan, Gordon B.; Stöckli, Reto; Covey, C.; Running, Steven W.; Fung, Inez

doi:10.1111/j.1365-2486.2009.01912.x

Cited by 349 publications

(309 citation statements)

References 93 publications

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“…Although an earlier version of CLM-CN had an attenuated seasonal cycle of atmospheric CO 2 across the northern hemisphere (19), introduction of a photoperiod correction on V cmax reduced bias and mean absolute error for seasonal cycle amplitude by 49% and 34%, respectively (mean of 60 stations globally) (Fig. 4 and Table S1).…”

Section: Resultsmentioning

confidence: 99%

“…As an evaluation of introducing a day-length correction on a broadly integrative global-scale metric, we gauged model performance with and without a simple photoperiod control for 1988-2004 to assess the amplitude and phase of seasonal cycles of atmospheric CO 2 concentration, using the C-LAMP protocol and metrics (19), adding observations from the southern hemisphere. Although an earlier version of CLM-CN had an attenuated seasonal cycle of atmospheric CO 2 across the northern hemisphere (19), introduction of a photoperiod correction on V cmax reduced bias and mean absolute error for seasonal cycle amplitude by 49% and 34%, respectively (mean of 60 stations globally) (Fig.…”

Section: Resultsmentioning

confidence: 99%

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Photoperiodic regulation of the seasonal pattern of photosynthetic capacity and the implications for carbon cycling

Bauerle

Oren²,

Way³

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

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Although temperature is an important driver of seasonal changes in photosynthetic physiology, photoperiod also regulates leaf activity. Climate change will extend growing seasons if temperature cues predominate, but photoperiod-controlled species will show limited responsiveness to warming. We show that photoperiod explains more seasonal variation in photosynthetic activity across 23 tree species than temperature. Although leaves remain green, photosynthetic capacity peaks just after summer solstice and declines with decreasing photoperiod, before air temperatures peak. In support of these findings, saplings grown at constant temperature but exposed to an extended photoperiod maintained high photosynthetic capacity, but photosynthetic activity declined in saplings experiencing a naturally shortening photoperiod; leaves remained equally green in both treatments. Incorporating a photoperiodic correction of photosynthetic physiology into a global-scale terrestrial carbon-cycle model significantly improves predictions of seasonal atmospheric CO 2 cycling, demonstrating the benefit of such a function in coupled climate system models. Accounting for photoperiod-induced seasonality in photosynthetic parameters reduces modeled global gross primary production 2.5% (∼4 PgC y −1 ), resulting in a >3% (∼2 PgC y −1 ) decrease of net primary production. Such a correction is also needed in models estimating current carbon uptake based on remotely sensed greenness. Photoperiod-associated declines in photosynthetic capacity could limit autumn carbon gain in forests, even if warming delays leaf senescence.day length | gross primary productivity | carbon sequestration | leaf area index | evapotranspiration W arming over the past 50 y has lengthened temperate growing seasons by 3.6 d per decade (1, 2). Longer growing seasons may increase net ecosystem productivity (2, 3), but increased spring carbon uptake has been accompanied by reduced autumn carbon uptake (2, 4). In extratropical ecosystems, where spring temperature is a major control on bud break, increased carbon sink strength has been linked to warmer April and May temperatures (3, 4), although drought can offset the increase in carbon uptake (5). The autumn switch from being a carbon sink to a carbon source in these ecosystems has been attributed to higher autumn temperatures, which are assumed to maintain high photosynthetic rates but even higher respiration rates (6). However, it is well known that leaf phenology responds to photoperiod, as well as temperature (7). Seasonal fluctuations in photosynthetic parameters are often modeled with temperature (8). However, photosynthetic physiology has also been shown to respond to photoperiod in controlled studies; instituting a short-day treatment in the fall, but maintaining high summer growth temperatures, inhibited the photosynthetic capacity of Pinus banksiana seedlings (9, 10). Seasonal measurements of photosynthetic capacity in trees under naturally changing photoperiod and air temperature signals are needed to ascertain whe...

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Photoperiodic regulation of the seasonal pattern of photosynthetic capacity and the implications for carbon cycling

Bauerle

Oren²,

Way³

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

273

214

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“…As a starting point, Stö ckli et al (2008) and Randerson et al (2009) have emphasized the importance of developing better data sets with which to test and evaluate model predictions. Comparative analyses of different phenological models have typically used data from only a single site (e.g., Richardson & O'Keefe, 2009), which hinders the development and parameterization of generalized models.…”

Section: Data Needsmentioning

confidence: 99%

“…They concluded that model bias toward under-predicting temperate and boreal forest uptake of CO 2 could be attributed to a 1-3 month delay in predicting the timing of maximum LAI in these ecosystems, compared to estimates derived from MODIS data. Randerson et al (2009) also noted that the two models they evaluated tended to predict a longer growing season than was actually observed in temperate ecosystems, with photosynthetic uptake occurring too early in the spring and too late in the autumn, compared with ground observations. Errors in LAI would likely propagate to errors in partitioning the available energy to latent and sensible heat fluxes, and errors in the timing of photosynthetic uptake would also affect the seasonality of modeled atmospheric CO 2 concentrations, emphasizing the importance of accurate representation of phenologically mediated processes.…”

Section: Introductionmentioning

confidence: 99%

“…Randerson et al (2009) included phenological metrics as part of a systematic framework, the Carbon-LAnd Model intercomparison Project (C-LAMP), to assess the biogeochemical component of coupled climate-carbon models. They concluded that model bias toward under-predicting temperate and boreal forest uptake of CO 2 could be attributed to a 1-3 month delay in predicting the timing of maximum LAI in these ecosystems, compared to estimates derived from MODIS data.…”

Section: Introductionmentioning

confidence: 99%

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Terrestrial biosphere models need better representation of vegetation phenology: results from the North American Carbon Program Site Synthesis

Richardson

Anderson

Arain

et al. 2011

Global Change Biology

643

536

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Phenology, by controlling the seasonal activity of vegetation on the land surface, plays a fundamental role in regulating photosynthesis and other ecosystem processes, as well as competitive interactions and feedbacks to the climate system. We conducted an analysis to evaluate the representation of phenology, and the associated seasonality of ecosystem-scale CO 2 exchange, in 14 models participating in the North American Carbon Program Site Synthesis. Model predictions were evaluated using long-term measurements (emphasizing the period 2000-2006) from 10 forested sites within the AmeriFlux and Fluxnet-Canada networks. In deciduous forests, almost all models consistently predicted that the growing season started earlier, and ended later, than was actually observed; biases of 2 weeks or more were 566-584, doi: 10.1111/j.1365-2486.2011.02562.x This article is a U.S. government work, and is not subject to copyright in the United States.Global Change Biology (2012) 18,typical. For these sites, most models were also unable to explain more than a small fraction of the observed interannual variability in phenological transition dates. Finally, for deciduous forests, misrepresentation of the seasonal cycle resulted in over-prediction of gross ecosystem photosynthesis by +160 ± 145 g C m À2 yr À1 during the spring transition period and +75 ± 130 g C m À2 yr À1 during the autumn transition period (13% and 8% annual productivity, respectively) compensating for the tendency of most models to under-predict the magnitude of peak summertime photosynthetic rates. Models did a better job of predicting the seasonality of CO 2 exchange for evergreen forests. These results highlight the need for improved understanding of the environmental controls on vegetation phenology and incorporation of this knowledge into better phenological models. Existing models are unlikely to predict future responses of phenology to climate change accurately and therefore will misrepresent the seasonality and interannual variability of key biosphere-atmosphere feedbacks and interactions in coupled global climate models.

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Evaluation and improvement of a global land model against soil carbon data using a Bayesian Markov chain Monte Carlo method

2014

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Long-term land carbon (C) cycle feedback to climate change is largely determined by dynamics of soil organic carbon (SOC). However, most evaluation studies conducted so far indicate that global land models predict SOC poorly. This study was conducted to evaluate predictions of SOC by the Community Land Model with Carnegie-Ames-Stanford Approach biogeochemistry submodel (CLM-CASA'), investigate underlying causes of mismatches between model predictions and observations, and calibrate model parameters to improve the prediction of SOC. We compared modeled SOC to the SOC pools from a globally gridded observation data product and found that CLM-CASA' on average underestimated SOC pools by 65% (r 2 = 0.28). We applied data assimilation to CLM-CASA' to estimate SOC residence times, C partitioning coefficients among the pools, and temperature sensitivity of C decomposition. The model with calibrated parameters explained 41% of the global variability in the observed SOC, which was substantial improvement from the initial 27%. The SOC and litter C feedback to changing climate differed between models with original and calibrated parameters: after 95 years of climate change (2006-2100), soils released 48 Pg C less in the calibrated than in the noncalibrated model and litter released 6.5 Pg C less in the calibrated than the noncalibrated model. Thus, assimilating estimated soil carbon data into the model improved model performance and reduced the amount of C released under changing climate. To further reduce the uncertainty in the soil carbon prediction, we need to explore alternative model structures, improve representation of ecosystems, and develop additional global datasets for constraining model parameters.

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Systematic assessment of terrestrial biogeochemistry in coupled climate–carbon models

Cited by 349 publications

References 93 publications

Photoperiodic regulation of the seasonal pattern of photosynthetic capacity and the implications for carbon cycling

Photoperiodic regulation of the seasonal pattern of photosynthetic capacity and the implications for carbon cycling

Terrestrial biosphere models need better representation of vegetation phenology: results from the North American Carbon Program Site Synthesis

Evaluation and improvement of a global land model against soil carbon data using a Bayesian Markov chain Monte Carlo method

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