Global variability in leaf respiration in relation to climate, plant functional types and leaf traits

Atkin, Owen K.; Bloomfield, Keith J.; Reich, Peter B.; Tjoelker, Mark G.; Asner, Gregory P.; Bonal, Damien; Bönisch, Gerhard; Bradford, Matt; Cernusak, Lucas A.; Cosio, Eric G.; Creek, Danielle; Crous, Kristine Y.; Domingues, Tomas F.; Dukes, Jeffrey S.; Egerton, John J. G.; Evans, John R.; Farquhar, Graham D.; Fyllas, Nikolaos M.; Gauthier, Paul P. G.; Gloor, Emanuel; Gimeno, Teresa E.; Griffin, Kevin L.; Guerrieri, Rossella; Heskel, Mary A.; Huntingford, Chris; Ishida, Françoise Yoko; Kattge, Jens; Lambers, Hans; Liddell, Michael J.; Lloyd, J.; Lusk, Christopher H.; Martin, Robert E.; Maksimov, Ayal; Maximov, Trofim C.; Malhi, Yadvinder; Medlyn, Belinda E.; Meir, Patrick; Mercado, Lina M.; Mirotchnick, Nicholas; Ng, Desmond; Niinemets, Ülo; O’Sullivan, Odhran S.; Phillips, Oliver L.; Poorter, Lourens; Poot, Pieter; Prentice, Iain Colin; Salinas, Norma; Rowland, Lucy; Ryan, Michael G.; Sitch, Stephen; Slot, Martijn; Smith, Nicholas G.; Turnbull, Matthew H.; Vanderwel, Mark C.; Valladares, Fernando; Veneklaas, Erik J.; Weerasinghe, Lasantha K.; Wirth, Christian; Wright, Ian J.; Wythers, Kirk R.; Xiang, Jen; Xiang, Shi‐Kai; Zaragoza‐Castells, Joana

doi:10.1111/nph.13253

Cited by 358 publications

(430 citation statements)

References 144 publications

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“…The traits studied here-SLA, Nm , and Pm -are central to predicting variation in rates of plant photosynthesis (5, 6, 9, 11) and foliar respiration (10,36). The importance of these traits and the more advanced representation of functional diversity developed here may be used to better capture the response of the land surface component of the Earth system to environmental change.…”

Section: Significancementioning

confidence: 99%

“…Multiple traits are critical to both photosynthesis and respiration, foremost leaf nitrogen concentration (Nm ) and specific leaf area (SLA) (5-7). More recently, variation in leaf phosphorus concentration (Pm ) has also been linked to variation in photosynthesis and foliar respiration (7)(8)(9)(10)(11)(12). Estimating detailed global geographic patterns of these traits and corresponding trait-environment relationships has been hampered by limited measurements (13), but recent improvements in data coverage (14) allow for greater detail in spatial estimates of these key traits.…”

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Mapping local and global variability in plant trait distributions

Butler

Datta

Flores‐Moreno

et al. 2017

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

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173

179

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Our ability to understand and predict the response of ecosystems to a changing environment depends on quantifying vegetation functional diversity. However, representing this diversity at the global scale is challenging. Typically, in Earth system models, characterization of plant diversity has been limited to grouping related species into plant functional types (PFTs), with all trait variation in a PFT collapsed into a single mean value that is applied globally. Using the largest global plant trait database and state of the art Bayesian modeling, we created fine-grained global maps of plant trait distributions that can be applied to Earth system models. Focusing on a set of plant traits closely coupled to photosynthesis and foliar respiration-specific leaf area (SLA) and dry mass-based concentrations of leaf nitrogen (Nm) and phosphorus (Pm), we characterize how traits vary within and among over 50,000 ∼50 × 50-km cells across the entire vegetated land surface. We do this in several ways-without defining the PFT of each grid cell and using 4 or 14 PFTs; each model's predictions are evaluated against out-of-sample data. This endeavor advances prior trait mapping by generating global maps that preserve variability across scales by using modern Bayesian spatial statistical modeling in combination with a database over three times larger than that in previous analyses. Our maps reveal that the most diverse grid cells possess trait variability close to the range of global PFT means.odeling global climate and the carbon cycle with Earth system models (ESMs) requires maps of plant traits that play key roles in leaf-and ecosystem-level metabolic processes (1-4). Multiple traits are critical to both photosynthesis and respiration, foremost leaf nitrogen concentration (Nm ) and specific leaf area (SLA) (5-7). More recently, variation in leaf phosphorus concentration (Pm ) has also been linked to variation in photosynthesis and foliar respiration (7-12). Estimating detailed global geographic patterns of these traits and corresponding trait-environment relationships has been hampered by limited measurements (13), but recent improvements in data coverage (14) allow for greater detail in spatial estimates of these key traits.Previous work has extrapolated trait measurements across continental or larger regions through three methodologies: (i) grouping measurements of individuals into larger categories that share a set of properties [a working definition of plant functional types (PFTs)] (4, 15), (ii) exploiting trait-environment relationships (e.g., leaf Nm and mean annual temperature) (1,(16)(17)(18)(19)(20), or (iii) restricting the analysis to species whose presence has been widely estimated on the ground (21-24). Each of these methods has limitations-for example, trait-environment relationships do not well explain observed trait spatial patterns (1, 25), while species-based approaches limit the scope of extrapolation to only areas with well-measured species abundance. More critically, the first two global methodologies emp...

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Section: Significancementioning

confidence: 99%

mentioning

confidence: 99%

Mapping local and global variability in plant trait distributions

Butler

Datta

Flores‐Moreno

et al. 2017

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

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173

179

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“…This is a major noted deficiency in current large-scale terrestrial models (Booth et al, 2012;Huntingford et al, 2013b;Smith and Dukes, 2013). In addition, the assessment of a newly available enhanced description of leaf dark respiration (Atkin et al, 2015) is needed, as well as the inclusion of both nitrogen and phosphorus constraints to plant productivity in tropical ecosystems (e.g. Mercado et al, 2011), and inclusion of a full representation of a coupled carbon-nitrogen cycle in JULES (Zaehle et al, 2010).…”

Section: Applicationsmentioning

confidence: 99%

Climate pattern-scaling set for an ensemble of 22 GCMs – adding uncertainty to the IMOGEN version 2.0 impact system

et al. 2018

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Abstract. Global circulation models (GCMs) are the best tool to understand climate change, as they attempt to represent all the important Earth system processes, including anthropogenic perturbation through fossil fuel burning. However, GCMs are computationally very expensive, which limits the number of simulations that can be made. Pattern scaling is an emulation technique that takes advantage of the fact that local and seasonal changes in surface climate are often approximately linear in the rate of warming over land and across the globe. This allows interpolation away from a limited number of available GCM simulations, to assess alternative future emissions scenarios. In this paper, we present a climate pattern-scaling set consisting of spatial climate change patterns along with parameters for an energybalance model that calculates the amount of global warming. The set, available for download, is derived from 22 GCMs of the WCRP CMIP3 database, setting the basis for similar eventual pattern development for the CMIP5 and forthcoming CMIP6 ensemble. Critically, it extends the use of the IMOGEN (Integrated Model Of Global Effects of climatic aNomalies) framework to enable scanning across full uncertainty in GCMs for impact studies. Across models, the presented climate patterns represent consistent global mean trends, with a maximum of 4 (out of 22) GCMs exhibiting the opposite sign to the global trend per variable (relative humidity). The described new climate regimes are generally warmer, wetter (but with less snowfall), cloudier and windier, and have decreased relative humidity. Overall, when averaging individual performance across all variables, and without considering co-variance, the patterns explain one-third of regional change in decadal averages (mean percentage variance explained, PVE, 34.25±5.21), but the signal in some models exhibits much more linearity (e.g. MIROC3.2(hires): 41.53) than in others (GISS_ER: 22.67). The two most often considered variables, near-surface temperature and precipitation, have a PVE of 85.44±4.37 and 14.98±4.61, respectively. We also provide an example assessment of a terrestrial impact (changes in mean runoff) and compare projections by the IMOGEN system, which has one land surface model, against direct GCM outputs, which all have alternative representations of land functioning. The latter is noted as an additional source of uncertainty. Finally, current and potential future applications of the IMOGEN version 2.0 modelling system in the areas of ecosystem modelling and climate change impact assessment are presented and discussed.

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“…The complex response of terrestrial ecosystem CO 2 exchanges to short-and long-term changes in temperature, water availability, nutrient availability, and rising atmospheric CO 2 (2-6) remains highly uncertain in C cycle model projections (7). As a result, there are large gaps in our understanding of terrestrial C dynamics, including the magnitude and residence times of the major ecosystem C pools (8,9) and rates of autotrophic respiration (10). Moreover, the impact of climatic extremes on C cycling, such as recent Amazon droughts (11), highlights the importance of understanding the terrestrial C cycle sensitivity to climate variability.…”

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confidence: 99%

The decadal state of the terrestrial carbon cycle: Global retrievals of terrestrial carbon allocation, pools, and residence times

Bloom

Exbrayat

Velde

et al. 2016

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

290

411

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The terrestrial carbon cycle is currently the least constrained component of the global carbon budget. Large uncertainties stem from a poor understanding of plant carbon allocation, stocks, residence times, and carbon use efficiency. Imposing observational constraints on the terrestrial carbon cycle and its processes is, therefore, necessary to better understand its current state and predict its future state. We combine a diagnostic ecosystem carbon model with satellite observations of leaf area and biomass (where and when available) and soil carbon data to retrieve the first global estimates, to our knowledge, of carbon cycle state and process variables at a 1°× 1°r esolution; retrieved variables are independent from the plant functional type and steady-state paradigms. Our results reveal global emergent relationships in the spatial distribution of key carbon cycle states and processes. Live biomass and dead organic carbon residence times exhibit contrasting spatial features (r = 0.3). Allocation to structural carbon is highest in the wet tropics (85-88%) in contrast to higher latitudes (73-82%), where allocation shifts toward photosynthetic carbon. Carbon use efficiency is lowest (0.42-0.44) in the wet tropics. We find an emergent global correlation between retrievals of leaf mass per leaf area and leaf lifespan (r = 0.64-0.80) that matches independent trait studies. We show that conventional land cover types cannot adequately describe the spatial variability of key carbon states and processes (multiple correlation median = 0.41). This mismatch has strong implications for the prediction of terrestrial carbon dynamics, which are currently based on globally applied parameters linked to land cover or plant functional types.carbon cycle | biomass | soil carbon | allocation | residence time T he terrestrial carbon (C) cycle remains the least constrained component of the global C budget (1). In contrast to a relatively stable increase of the ocean CO 2 sink from 0.9 to 2.7 Pg C y −1 over the past 40 y, terrestrial CO 2 uptake has been found to vary between a net 4.1-Pg C y −1 sink to a 0.4-Pg C y −1 source, and accounts for a majority of the interannual variability in atmospheric CO 2 growth. The complex response of terrestrial ecosystem CO 2 exchanges to short-and long-term changes in temperature, water availability, nutrient availability, and rising atmospheric CO 2 (2-6) remains highly uncertain in C cycle model projections (7). As a result, there are large gaps in our understanding of terrestrial C dynamics, including the magnitude and residence times of the major ecosystem C pools (8, 9) and rates of autotrophic respiration (10). Moreover, the impact of climatic extremes on C cycling, such as recent Amazon droughts (11), highlights the importance of understanding the terrestrial C cycle sensitivity to climate variability. To understand terrestrial CO 2 exchanges in the past, present, and future, we need to better constrain current dynamics of ecosystem C cycling from regional to global scales.C uptake, allocati...

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Global variability in leaf respiration in relation to climate, plant functional types and leaf traits

Cited by 358 publications

References 144 publications

Mapping local and global variability in plant trait distributions

Mapping local and global variability in plant trait distributions

Climate pattern-scaling set for an ensemble of 22 GCMs – adding uncertainty to the IMOGEN version 2.0 impact system

The decadal state of the terrestrial carbon cycle: Global retrievals of terrestrial carbon allocation, pools, and residence times

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