Role of CO2, climate and land use in regulating the seasonal amplitude increase of carbon fluxes in terrestrial ecosystems: a multimodel analysis

Abstract. We examined the net terrestrial carbon flux to the atmosphere (FTA) simulated by nine models from the TRENDY dynamic global vegetation model project for its seasonal cycle and amplitude trend during 1961–2012. While some models exhibit similar phase and amplitude compared to atmospheric inversions, with spring drawdown and autumn rebound, others tend to rebound early in summer. The model ensemble mean underestimates the magnitude of the seasonal cycle by 40 % compared to atmospheric inversions. Global FTA amplitude increase (19 ± 8 %) and its decadal variability from the model ensemble are generally consistent with constraints from surface atmosphere observations. However, models disagree on attribution of this long-term amplitude increase, with factorial experiments attributing 83 ± 56 %, −3 ± 74 and 20 ± 30 % to rising CO2, climate change and land use/cover change, respectively. Seven out of the nine models suggest that CO2 fertilization is the strongest control – with the notable exception of VEGAS, which attributes approximately equally to the three factors. Generally, all models display an enhanced seasonality over the boreal region in response to high-latitude warming, but a negative climate contribution from part of the Northern Hemisphere temperate region, and the net result is a divergence over climate change effect. Six of the nine models show that land use/cover change amplifies the seasonal cycle of global FTA: some are due to forest regrowth, while others are caused by crop expansion or agricultural intensification, as revealed by their divergent spatial patterns. We also discovered a moderate cross-model correlation between FTA amplitude increase and increase in land carbon sink (R2 =  0.61). Our results suggest that models can show similar results in some benchmarks with different underlying mechanisms; therefore, the spatial traits of CO2 fertilization, climate change and land use/cover changes are crucial in determining the right mechanisms in seasonal carbon cycle change as well as mean sink change.

[1]  K. Thonicke,et al.  Identifying environmental controls on vegetation greenness phenology through model–data integration , 2014 .

[2]  P. Cox,et al.  The Joint UK Land Environment Simulator (JULES), model description – Part 2: Carbon fluxes and vegetation dynamics , 2011 .

[3]  R. Schnur,et al.  Climate-carbon cycle feedback analysis: Results from the C , 2006 .

[4]  Inez Y. Fung,et al.  The changing carbon cycle at Mauna Loa Observatory , 2007, Proceedings of the National Academy of Sciences.

[5]  I. C. Prentice,et al.  A dynamic global vegetation model for studies of the coupled atmosphere‐biosphere system , 2005 .

[6]  J. Randerson,et al.  An atmospheric perspective on North American carbon dioxide exchange: CarbonTracker , 2007, Proceedings of the National Academy of Sciences.

[7]  Stephen Sitch,et al.  Evaluation of terrestrial carbon cycle models through simulations of the seasonal cycle of atmospheric CO2: First results of a model intercomparison study , 1998 .

[8]  Sönke Zaehle,et al.  Towards a more objective evaluation of modelled land-carbon trends using atmospheric CO 2 and satellite-based vegetation activity observations , 2013 .

[9]  C. Jones,et al.  Development and evaluation of an Earth-System model - HadGEM2 , 2011 .

[10]  G. Pearman,et al.  Activities of the global biosphere as reflected in atmospheric CO2 records , 1980 .

[11]  F. Joos,et al.  Rates of change in natural and anthropogenic radiative forcing over the past 20,000 years , 2008, Proceedings of the National Academy of Sciences.

[12]  Luis Guanter,et al.  Agricultural Green Revolution as a driver of increasing atmospheric CO2 seasonal amplitude , 2014, Nature.

[13]  Nicolas Gruber,et al.  Trends and regional distributions of land and ocean carbon sinks , 2009 .

[14]  Thomas Kaminski,et al.  Sensitivity of the seasonal cycle of CO2 at remote monitoring stations with respect to seasonal surface exchange fluxes determined with the adjoint of an atmospheric transport model , 1996 .

[15]  M. Wahlen,et al.  Interannual extremes in the rate of rise of atmospheric carbon dioxide since 1980 , 1995, Nature.

[16]  K.,et al.  Carbon–Concentration and Carbon–Climate Feedbacks in CMIP5 Earth System Models , 2012 .

[17]  Yoshiki Yamagata,et al.  Evaluation of spatially explicit emission scenario of land-use change and biomass burning using a process-based biogeochemical model , 2013 .

[18]  Andrew D. Friend,et al.  Carbon and nitrogen cycle dynamics in the O‐CN land surface model: 1. Model description, site‐scale evaluation, and sensitivity to parameter estimates , 2010 .

[19]  Robert B. Cook,et al.  The North American Carbon Program Multi-scale Synthesis and Terrestrial Model Intercomparison Project – Part 2: Environmental driver data , 2013 .

[20]  I. Wing,et al.  Net carbon uptake has increased through warming-induced changes in temperate forest phenology , 2014 .

[21]  R. Schnur,et al.  Separation of the Effects of Land and Climate Model Errors on Simulated Contemporary Land Carbon Cycle Trends in the MPI Earth System Model version 1 , 2015 .

[22]  Kevin R. Gurney,et al.  Regional trends in terrestrial carbon exchange and their seasonal signatures , 2011 .

[23]  C. Tucker,et al.  Increased plant growth in the northern high latitudes from 1981 to 1991 , 1997, Nature.

[24]  Philippe Ciais,et al.  Benchmarking the seasonal cycle of CO2 fluxes simulated by terrestrial ecosystem models , 2015 .

[25]  Kees Klein Goldewijk,et al.  The HYDE 3.1 spatially explicit database of human‐induced global land‐use change over the past 12,000 years , 2011 .

[26]  Ranga B. Myneni,et al.  Recent trends and drivers of regional sources and sinks of carbon dioxide , 2015 .

[27]  Zong-Liang Yang,et al.  Technical description of version 4.5 of the Community Land Model (CLM) , 2013 .

[28]  Atul K. Jain,et al.  Global carbon budget 2013 , 2013 .

[29]  Atul K. Jain,et al.  Global Carbon Budget 2018 , 2014, Earth System Science Data.

[30]  E. A. Kort,et al.  Enhanced Seasonal Exchange of CO2 by Northern Ecosystems Since 1960 , 2013, Science.

[31]  Pierre Friedlingstein,et al.  Uncertainties in CMIP5 Climate Projections due to Carbon Cycle Feedbacks , 2014 .

[32]  Atul K. Jain,et al.  Global Carbon Budget 2018 , 2014, Earth System Science Data.

[33]  P. Ciais,et al.  Sensitivity of global terrestrial carbon cycle dynamics to variability in satellite‐observed burned area , 2015 .

[34]  Atul K. Jain,et al.  Decadal trends in the seasonal-cycle amplitude of terrestrial CO2 exchange resulting from the ensemble of terrestrial biosphere models , 2016 .

[35]  J. R. Trabalka,et al.  The Changing Carbon Cycle: A Global Analysis , 1986 .

[36]  Corinne Le Quéré,et al.  Trends and drivers of regional sources and sinks of carbon dioxide over the past two decades , 2013 .

[37]  A. Mariotti,et al.  Terrestrial mechanisms of interannual CO2 variability , 2005 .

[38]  Christopher B. Field,et al.  The contribution of terrestrial sources and sinks to trends in the seasonal cycle of atmospheric carbon dioxide , 1997 .

[39]  J. Randerson,et al.  New constraints on Northern Hemisphere growing season net flux , 2007 .

[40]  F. Joos,et al.  DYPTOP: a cost-efficient TOPMODEL implementation to simulate sub-grid spatio-temporal dynamics of global wetlands and peatlands , 2014 .

[41]  C. D. Keeling,et al.  Seasonal Amplitude Increase in Atmospheric Concentration , 1985 .

[42]  R. Thompson The relationship of the phase and amplitude of the annual cycle of CO2 to phenological events , 2011 .

[43]  Mark A. Friedl,et al.  Direct human influence on atmospheric CO2 seasonality from increased cropland productivity , 2014, Nature.

[44]  P. Reich,et al.  Decade-long soil nitrogen constraint on the CO2 fertilization of plant biomass , 2013 .

[45]  K. Davis,et al.  Large amplitude spatial and temporal gradients in atmospheric boundary layer CO2mole fractions detected with a tower-based network in the U.S. upper Midwest , 2012 .

[46]  I. C. Prentice,et al.  Carbon balance of the terrestrial biosphere in the Twentieth Century: Analyses of CO2, climate and land use effects with four process‐based ecosystem models , 2001 .

[47]  Stephen Sitch,et al.  The Carbon Balance of the Terrestrial Biosphere: Ecosystem Models and Atmospheric Observations , 2000 .

[48]  P. Tans,et al.  Atmospheric carbon dioxide at Mauna Loa Observatory: 2. Analysis of the NOAA GMCC data, 1974–1985 , 1989 .

[49]  C. D. Keeling,et al.  Increased activity of northern vegetation inferred from atmospheric CO2 measurements , 1996, Nature.

[50]  David Medvigy,et al.  Identification and characterization of abrupt changes in the land uptake of carbon , 2012 .

[51]  S S I T C H,et al.  Evaluation of Ecosystem Dynamics, Plant Geography and Terrestrial Carbon Cycling in the Lpj Dynamic Global Vegetation Model , 2022 .

[52]  W. Dieleman,et al.  Effects of elevated CO 2 and N fertilization on plant and soil carbon pools of managed grasslands: a meta-analysis , 2012 .

[53]  Pieter P. Tans,et al.  Extension and integration of atmospheric carbon dioxide data into a globally consistent measurement record , 1995 .

[54]  Fang Zhao,et al.  Global and Regional Variability and Change in Terrestrial Ecosystems Net Primary Production and NDVI: A Model-Data Comparison , 2016, Remote. Sens..

[55]  Haifeng Qian,et al.  Impact of 1998–2002 midlatitude drought and warming on terrestrial ecosystem and the global carbon cycle , 2005 .

[56]  G. Alexandrov Explaining the seasonal cycle of the globally averaged CO 2 with a carbon-cycle model , 2014 .

[57]  N. Zeng,et al.  Continued increase in atmospheric CO 2 seasonal amplitude in the 21st century projected by the CMIP5 Earth system models , 2014 .

[58]  W. Post,et al.  The North American Carbon Program Multi-Scale Synthesis and Terrestrial Model Intercomparison Project – Part 1: Overview and experimental design , 2013 .

[59]  Maximilian Reuter,et al.  Terrestrial carbon sink observed from space: variation of growth rates and seasonal cycle amplitudes in response to interannual surface temperature variability , 2013 .

[60]  Y. Niwa,et al.  Global atmospheric carbon budget: results from an ensemble of atmospheric CO2 inversions. , 2013 .

[61]  F. Harris On the use of windows for harmonic analysis with the discrete Fourier transform , 1978, Proceedings of the IEEE.

[62]  Robert J. Scholes,et al.  The Carbon Cycle and Atmospheric Carbon Dioxide , 2001 .

[63]  Atul K. Jain,et al.  CO2 emissions from land‐use change affected more by nitrogen cycle, than by the choice of land‐cover data , 2013, Global change biology.

[64]  Christopher B. Field,et al.  Increases in early season ecosystem uptake explain recent changes in the seasonal cycle of atmospheric CO2 at high northern latitudes , 1999 .

[65]  C. Hall,et al.  A fifteen-year record of biotic metabolism in the Northern Hemisphere , 1975, Nature.

[66]  Sander Houweling,et al.  CO 2 flux history 1982–2001 inferred from atmospheric data using a global inversion of atmospheric transport , 2003 .

[67]  Philippe Ciais,et al.  Carbon benefits of anthropogenic reactive nitrogen offset by nitrous oxide emissions , 2011 .

[68]  S. Zaehle,et al.  Enhanced seasonal CO_2 exchange caused by amplified plant productivity in northern ecosystems, link to model results , 2016 .