Recent pause in the growth rate of atmospheric CO2 due to enhanced terrestrial carbon uptake

Keenan, Trevor F.; Prentice, Iain Colin; Canadell, Josep G.; Williams, C. A.; Wang, Han; Raupach, Michael; Collatz, G. J.

doi:10.1038/ncomms13428

Cited by 373 publications

(327 citation statements)

References 70 publications

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“…, Keenan et al. ), yet, how to increase the climate change mitigation function of forests remains an active debate among scientists, practitioners, and policy makers. While forest management has been promoted as a driver for active climate change mitigation (Canadell and Raupach , Lundmark et al.…”

Section: Introductionmentioning

confidence: 99%

The impact of future forest dynamics on climate: interactive effects of changing vegetation and disturbance regimes

Thom

Rammer

Seidl

2017

Ecological Monographs

104

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Currently, the temperate forest biome cools the earth's climate and dampens anthropogenic climate change. However, climate change will substantially alter forest dynamics in the future, affecting the climate regulation function of forests. Increasing natural disturbances can reduce carbon uptake and evaporative cooling, but at the same time increase the albedo of a landscape. Simultaneous changes in vegetation composition can mitigate disturbance impacts, but also influence climate regulation directly (e.g., via albedo changes). As a result of a number of interactive drivers (changes in climate, vegetation, and disturbance) and their simultaneous effects on climate-relevant processes (carbon exchange, albedo, latent heat flux) the future climate regulation function of forests remains highly uncertain. Here we address these complex interactions to assess the effect of future forest dynamics on the climate system. Our specific objectives were (1) to investigate the long-term interactions between changing vegetation composition and disturbance regimes under climate change, (2) to quantify the response of climate regulation to changes in forest dynamics, and (3) to identify the main drivers of the future influence of forests on the climate system. We investigated these issues using the individual-based forest landscape and disturbance model (iLand). Simulations were run over 200 yr for Kalkalpen National Park (Austria), assuming different future climate projections, and incorporating dynamically responding wind and bark beetle disturbances. To consistently assess the net effect on climate the simulated responses of carbon exchange, albedo, and latent heat flux were expressed as contributions to radiative forcing. We found that climate change increased disturbances (+27.7% over 200 yr) and specifically bark beetle activity during the 21st century. However, negative feedbacks from a simultaneously changing tree species composition (+28.0% broadleaved species) decreased disturbance activity in the long run (-10.1%), mainly by reducing the host trees available for bark beetles. Climate change and the resulting future forest dynamics significantly reduced the climate regulation function of the landscape, increasing radiative forcing by up to +10.2% on average over 200 yr. Overall, radiative forcing was most strongly driven by carbon exchange. We conclude that future changes in forest dynamics can cause amplifying climate feedbacks from temperate forest ecosystems.

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Section: Introductionmentioning

confidence: 99%

The impact of future forest dynamics on climate: interactive effects of changing vegetation and disturbance regimes

Thom

Rammer

Seidl

2017

Ecological Monographs

104

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“…For example, it is remarkable that the incremental trend continued in Asia, Africa, Europe, and North America after 2000 but almost completely disappeared in Oceania and South America. This period of the 2000s is known as the hiatus of global warming, leading to an unexpected depression of the atmospheric CO 2 growth rate probably due to suppressed ecosystem respiration (Keenan et al 2016, Ballantyne et al 2017. A regional analysis of GPP may provide a supporting evidence for the recent perturbations in the global carbon cycle, although further in-depth analyses are required.…”

Section: Mechanistic Findings From Benchmarkingmentioning

confidence: 99%

Photosynthetic productivity and its efficiencies in ISIMIP2a biome models: benchmarking for impact assessment studies

Ito

Nishina

Reyer

et al. 2017

Environ. Res. Lett.

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“…Globally averaged concentrations of atmospheric CO 2 have increased from 280 ppm since the Industrial Revolution (Bauska et al, 2015; Etheridge et al, 1996) to 403.3 ppm in 2016 (WMO, 2017). The growth rate of atmospheric CO 2 concentrations, which represents the additional burden of CO 2 for a given year integrated over all sources and sinks, remained about 2 ppm/year after 2010 (Keenan et al, 2016) but has been as large as 2.96 ppm/year in 2015 due to the tropical outgassing arising from the El Nino (Yue et al, 2017). On the global scale, the ocean and the terrestrial biosphere remove approximately 45% of the CO 2 emitted by human activities each year (Le Quéré et al, 2015), though the interannual variability in the global sink is large.…”

Section: Introductionmentioning

confidence: 99%

Terrestrial CO₂ Fluxes, Concentrations, Sources and Budget in Northeast China: Observational and Modeling Studies

Cai

et al. 2020

JGR Atmospheres

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CO2 fluxes and concentrations are not well understood in Northeast China, where dominant land surface types are mixed forest and cropland. Here, we analyzed the CO2 fluxes and concentrations using observations and the Weather Research and Forecasting model coupled with the Vegetation Photosynthesis and Respiration Model (WRF‐VPRM). We also used WRF‐VPRM outputs to examine CO2 transport/dispersion and budgets. Finally, we investigated the uncertainties of simulating CO2 fluxes related to four VPRM parameters (including maximum light use efficiency, photosynthetically active radiation half‐saturation value, and two respiration parameters) using off‐line ensemble simulations. The results indicated that mixed forests acted as a larger CO2 source and sink than rice paddies in 2016 due to a longer growth period and stronger ecosystem respiration, although measured minimum daily mean net ecosystem exchange (NEE) was smaller at rice paddy (−10 μmol·m‐2·s‐1) than at mixed forest (−6.5 μmol·m‐2·s‐1) during the growing season (May–September). The monthly fluctuation of column‐averaged CO2 concentrations (XCO2) exceeded 10 ppm in Northeast China during 2016. The large summertime biogenic sinks offset about 70% of anthropogenic contribution of XCO2 in this region. WRF‐VPRM modeling successfully captured seasonal and episodic variations of NEE and CO2 concentrations; however, NEE in mixed forest was overestimated during daytime, mainly due to the uncertainties of VPRM parameters, especially maximum light use efficiency. These findings suggest that the WRF‐VPRM modeling framework will provide greater understanding of the natural and anthropogenic contributions to the carbon cycle in China, especially after calibration of parameters that control biogenic fluxes.

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Recent pause in the growth rate of atmospheric CO2 due to enhanced terrestrial carbon uptake

Cited by 373 publications

References 70 publications

The impact of future forest dynamics on climate: interactive effects of changing vegetation and disturbance regimes

The impact of future forest dynamics on climate: interactive effects of changing vegetation and disturbance regimes

Photosynthetic productivity and its efficiencies in ISIMIP2a biome models: benchmarking for impact assessment studies

Terrestrial CO₂ Fluxes, Concentrations, Sources and Budget in Northeast China: Observational and Modeling Studies

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Recent pause in the growth rate of atmospheric CO2 due to enhanced terrestrial carbon uptake

Cited by 373 publications

References 70 publications

The impact of future forest dynamics on climate: interactive effects of changing vegetation and disturbance regimes

The impact of future forest dynamics on climate: interactive effects of changing vegetation and disturbance regimes

Photosynthetic productivity and its efficiencies in ISIMIP2a biome models: benchmarking for impact assessment studies

Terrestrial CO2 Fluxes, Concentrations, Sources and Budget in Northeast China: Observational and Modeling Studies

Contact Info

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Terrestrial CO₂ Fluxes, Concentrations, Sources and Budget in Northeast China: Observational and Modeling Studies