Changes in Wood Biomass and Crop Yields in Response to Projected CO2, O3, Nitrogen Deposition, and Climate

As the world's population increases, so will the demand for food and timber resources. Though carbon dioxide (CO2) fertilization and, to a lesser extent, nitrogen (N) deposition are expected to increase future resource production, changes in ozone (O3) and climate have the potential to decrease production due to increased phytotoxic damage, drought, and heat stress. To determine how crop and timber production may change in the future, we use the Community Land Model version 4.5 with prognostic crops to simulate responses of wood biomass and crop yields to CO2, O3, N deposition, and climate under Representative Concentration Pathway 8.5 forcings. Generally, rising CO2 increases wood biomass and crop yields, while projected climate change causes decreases. Small projected changes in O3 and N deposition do not strongly affect yields, though additional research is needed on future O3 and N deposition trends and impacts. By the end of the 21st century, global wood biomass increases by ~16% due to the dominating impact of CO2. The positive effect of CO2 on future crop yields is muted by the negative impacts of climate, with a ~5% net global increase. Future projections suggest that rice and wheat yields typically increase under the combination of future forcings, whereas soy and corn yields are regionally variable. While short‐term resource management strategies can benefit from planting heat‐tolerant species and cultivars, technological advances and intensification, among other management strategies not included here, must be employed to meet the future demand for these resources.

[1]  G. Bonan,et al.  Triose phosphate limitation in photosynthesis models reduces leaf photosynthesis and global terrestrial carbon storage , 2018, Environmental Research Letters.

[2]  S. Levis,et al.  CLMcrop yields and water requirements: avoided impacts by choosing RCP 4.5 over 8.5 , 2018, Climatic Change.

[3]  P. Ciais,et al.  Global forest carbon uptake due to nitrogen and phosphorus deposition from 1850 to 2100 , 2017, Global change biology.

[4]  Gordon B. Bonan,et al.  Reducing uncertainty in projections of terrestrial carbon uptake , 2017 .

[5]  N. Unger,et al.  Limited effect of ozone reductions on the 20‐year photosynthesis trend at Harvard forest , 2016, Global change biology.

[6]  D. Shindell Crop yield changes induced by emissions of individual climate‐altering pollutants , 2016 .

[7]  Steven W. Running,et al.  Large divergence of satellite and Earth system model estimates of global terrestrial CO2 fertilization , 2016 .

[8]  M. Lerdau,et al.  Forests and ozone: productivity, carbon storage, and feedbacks , 2016, Scientific Reports.

[9]  Yingtian Xie,et al.  Responses of wheat and rice to factorial combinations of ambient and elevated CO2 and temperature in FACE experiments , 2016, Global change biology.

[10]  P. Dirmeyer,et al.  Climate response to Amazon forest replacement by heterogeneous crop cover , 2015 .

[11]  P. Ciais,et al.  A simplified, data-constrained approach to estimate the permafrost carbon–climate feedback , 2015, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[12]  Benjamin Leon Bodirsky,et al.  Global Food Demand Scenarios for the 21st Century , 2015, PloS one.

[13]  J. McGrath,et al.  An analysis of ozone damage to historical maize and soybean yields in the United States , 2015, Proceedings of the National Academy of Sciences.

[14]  Donald R Ort,et al.  Canopy warming caused photosynthetic acclimation and reduced seed yield in maize grown at ambient and elevated [CO2] , 2015, Global change biology.

[15]  D. Lawrence,et al.  Permafrost thaw and resulting soil moisture changes regulate projected high-latitude CO2 and CH4 emissions , 2015 .

[16]  Itai Kloog,et al.  Impacts of elevated atmospheric CO2 on nutrient content of important food crops , 2015, Scientific Data.

[17]  K. Nicholas,et al.  How climate change affects extremes in maize and wheat yield in two cropping regions , 2015 .

[18]  Jeffrey W. White,et al.  Rising Temperatures Reduce Global Wheat Production , 2015 .

[19]  Ke Zhang,et al.  The fate of Amazonian ecosystems over the coming century arising from changes in climate, atmospheric CO2, and land use , 2015, Global change biology.

[20]  David B Lobell,et al.  The fingerprint of climate trends on European crop yields , 2014, Proceedings of the National Academy of Sciences.

[21]  P. Reich,et al.  Plant growth enhancement by elevated CO2 eliminated by joint water and nitrogen limitation , 2014 .

[22]  C. Heald,et al.  Threat to future global food security from climate change and ozone air pollution , 2014 .

[23]  V. Ramanathan,et al.  Reductions in India's crop yield due to ozone , 2014 .

[24]  G. Holland,et al.  Projections of future summertime ozone over the U.S. , 2014 .

[25]  A. Zanobetti,et al.  Increasing CO2 threatens human nutrition , 2014, Nature.

[26]  C. Holmes Air pollution and forest water use , 2014, Nature.

[27]  D. Lombardozzi,et al.  Integrating O 3 influences on terrestrial processes: photosynthetic and stomatal response data available for regional and global modeling , 2013 .

[28]  R. Q. Thomas,et al.  Global patterns of nitrogen limitation: confronting two global biogeochemical models with observations , 2013, Global change biology.

[29]  J. von Braun,et al.  Climate Change Impacts on Global Food Security , 2013, Science.

[30]  Hans Peter Schmid,et al.  Increase in forest water-use efficiency as atmospheric carbon dioxide concentrations rise , 2013, Nature.

[31]  R. Q. Thomas,et al.  Insights into mechanisms governing forest carbon response to nitrogen deposition: A model–data comparison using observed responses to nitrogen addition , 2013 .

[32]  Mark A. White,et al.  Sensitivity of Russian forest timber harvest and carbon storage to temperature increase , 2013 .

[33]  Keith Goulding,et al.  Enhanced nitrogen deposition over China , 2013, Nature.

[34]  Robert Jacob,et al.  Modeling agriculture in the Community Land Model , 2012 .

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

[36]  J. Lamarque,et al.  Pre-industrial to end 21st century projections of tropospheric ozone from the Atmospheric Chemistry and Climate Model Intercomparison Project (ACCMIP) , 2012 .

[37]  Peter E. Thornton,et al.  Interactive Crop Management in the Community Earth System Model (CESM1): Seasonal Influences on Land–Atmosphere Fluxes , 2012 .

[38]  W. G. Strand,et al.  Climate System Response to External Forcings and Climate Change Projections in CCSM4 , 2012 .

[39]  Stephen Sitch,et al.  The effects of tropospheric ozone on net primary productivity and implications for climate change. , 2012, Annual review of plant biology.

[40]  Elizabeth A. Ainsworth,et al.  Quantifying the effects of ozone on plant reproductive growth and development , 2012 .

[41]  G. Bonan,et al.  Ozone exposure causes a decoupling of conductance and photosynthesis: implications for the Ball-Berry stomatal conductance model , 2012, Oecologia.

[42]  Veronika Eyring,et al.  Ozone database in support of CMIP5 simulations: results and corresponding radiative forcing , 2011 .

[43]  N. Nakicenovic,et al.  RCP 8.5—A scenario of comparatively high greenhouse gas emissions , 2011 .

[44]  G. P. Kyle,et al.  Global and regional evolution of short-lived radiatively-active gases and aerosols in the Representative Concentration Pathways , 2011 .

[45]  John P. Weyant,et al.  A special issue on the RCPs , 2011 .

[46]  A. Thomson,et al.  The representative concentration pathways: an overview , 2011 .

[47]  Richard Betts,et al.  Implications of climate change for agricultural productivity in the early twenty-first century , 2010, Philosophical Transactions of the Royal Society B: Biological Sciences.

[48]  D. Ellsworth,et al.  Stomatal uptake of O3 in aspen and aspen-birch forests under free-air CO2 and O3 enrichment. , 2010, Environmental pollution.

[49]  P. Döll,et al.  MIRCA2000—Global monthly irrigated and rainfed crop areas around the year 2000: A new high‐resolution data set for agricultural and hydrological modeling , 2010 .

[50]  Y. Malhi,et al.  Carbon cost of plant nitrogen acquisition: A mechanistic, globally applicable model of plant nitrogen uptake, retranslocation, and fixation , 2010 .

[51]  G. Wieser,et al.  Air pollution and climate change effects on forest ecosystems: new evidence , 2010, European Journal of Forest Research.

[52]  S. Luyssaert,et al.  Carbon cycle: Nitrogen's carbon bonus , 2009 .

[53]  Xin-ping Chen,et al.  Reducing environmental risk by improving N management in intensive Chinese agricultural systems , 2009, Proceedings of the National Academy of Sciences.

[54]  F. Woodward,et al.  Using temperature‐dependent changes in leaf scaling relationships to quantitatively account for thermal acclimation of respiration in a coupled global climate–vegetation model , 2008 .

[55]  E. Ainsworth,et al.  Impact of elevated ozone concentration on growth, physiology, and yield of wheat (Triticum aestivum L.): a meta‐analysis , 2008 .

[56]  Mark A. Sutton,et al.  Uncertainties in the relationship between atmospheric nitrogen deposition and forest carbon sequestration , 2008 .

[57]  Richard A. Feely,et al.  Global nitrogen deposition and carbon sinks , 2008 .

[58]  A. Rogers,et al.  ’ s Choice Series on the Next Generation of Biotech Crops Targets for Crop Biotechnology in a Future High-CO 2 and High-O 3 World 1 , 2008 .

[59]  S. Long,et al.  To what extent do current and projected increases in surface ozone affect photosynthesis and stomatal conductance of trees? A meta-analytic review of the last 3 decades of experiments. , 2007, Plant, cell & environment.

[60]  Jens Kattge,et al.  Temperature acclimation in a biochemical model of photosynthesis: a reanalysis of data from 36 species. , 2007, Plant, cell & environment.

[61]  P. Hari,et al.  The human footprint in the carbon cycle of temperate and boreal forests , 2007, Nature.

[62]  A. Rogers,et al.  The response of photosynthesis and stomatal conductance to rising [CO2]: mechanisms and environmental interactions. , 2007, Plant, cell & environment.

[63]  S. Long,et al.  Food for Thought: Lower-Than-Expected Crop Yield Stimulation with Rising CO2 Concentrations , 2006, Science.

[64]  D. Timlin,et al.  Canopy photosynthesis, evapotranspiration, leaf nitrogen, and transcription profiles of maize in response to CO2 enrichment , 2006 .

[65]  Pete Smith,et al.  The potential distribution of bioenergy crops in the UK under present and future climate , 2006 .

[66]  T. Tschaplinski,et al.  Importance of changing CO2, temperature, precipitation, and ozone on carbon and water cycles of an upland‐oak forest: incorporating experimental results into model simulations , 2005 .

[67]  D. Karnosky Ozone Effects on Forest Ecosystems under a Changing Global Environment , 2005 .

[68]  S. Long,et al.  What have we learned from 15 years of free-air CO2 enrichment (FACE)? A meta-analytic review of the responses of photosynthesis, canopy properties and plant production to rising CO2. , 2004, The New phytologist.

[69]  G. Meehl,et al.  More Intense, More Frequent, and Longer Lasting Heat Waves in the 21st Century , 2004, Science.

[70]  J. Rebbeck,et al.  Foliar physiology of yellow-poplar ( Liriodendron tulipifera L.) exposed to O3 and elevated CO2 over five seasons. , 2004, Trees.

[71]  D. Eamus,et al.  Mechanisms underlying the amelioration of O3-induced damage by elevated atmospheric concentrations of CO2. , 2004, Journal of experimental botany.

[72]  S. Long,et al.  How does elevated ozone impact soybean? A meta‐analysis of photosynthesis, growth and yield , 2003 .

[73]  R. E. Dickson,et al.  Tropospheric O3 moderates responses of temperate hardwood forests to elevated CO2: a synthesis of molecular to ecosystem results from the Aspen FACE project , 2003 .

[74]  Denise L. Mauzerall,et al.  PROTECTING AGRICULTURAL CROPS FROM THE EFFECTS OF TROPOSPHERIC OZONE EXPOSURE: Reconciling Science and Standard Setting in the United States, Europe, and Asia , 2001 .

[75]  C. Andersen,et al.  Blue wild-rye grass competition increases the effect of ozone on ponderosa pine seedlings. , 2001, Tree physiology.

[76]  P. Curtis,et al.  Atmospheric Co2, Soil‐N Availability, And Allocation Of Biomass And Nitrogen By Populus Tremuloides , 2000 .

[77]  J. Rebbeck,et al.  Interactive effects of ozone and elevated carbon dioxide on the growth and physiology of black cherry, green ash, and yellow-poplar seedlings. , 1999, Environmental pollution.

[78]  B. Emmett,et al.  Nitrogen deposition makes a minor contribution to carbon sequestration in temperate forests , 1999, Nature.

[79]  G. Likens,et al.  Technical Report: Human Alteration of the Global Nitrogen Cycle: Sources and Consequences , 1997 .

[80]  R. Rowland,et al.  Photosynthetic Characteristics in Wheat Exposed to Elevated O3 and CO2 , 1996 .

[81]  Mark A. Delucchi,et al.  The cost of crop damage caused by ozone air pollution from motor vehicles , 1996 .

[82]  T. Wigley,et al.  Influences of precipitation changes and direct CO2 effects on streamflow , 1985, Nature.

[83]  G. Bonan,et al.  The Influence of Chronic Ozone Exposure on Global Carbon and Water Cycles , 2015 .

[84]  F. Bongers,et al.  No growth stimulation of tropical trees by 150 years of CO2 fertilization but water-use efficiency increased , 2015 .

[85]  C. Infante,et al.  Atmospheric Nitrogen Deposition can Provide Supplementary Fertilization to Sugar Cane Crops in Venezuela , 2014 .

[86]  M. Lanfranchi,et al.  Economic Implications of Climate Change for Agricultural Productivity , 2014 .

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

[88]  Charles D. Canham,et al.  Increased tree carbon storage in response to nitrogen deposition in the US , 2010 .

[89]  D. Ellsworth,et al.  Stomatal uptake of O 3 in aspen and aspen-birch forests under free-air CO 2 and O 3 enrichment , 2010 .

[90]  Janusz Cofala,et al.  The global impact of ozone on agricultural crop yields under current and future air quality legislation , 2009 .

[91]  L. J. H. A N S O N,et al.  Importance of changing CO 2 , temperature, precipitation, and ozone on carbon and water cycles of an upland-oak forest: incorporating experimental results into model simulations , 2005 .

[92]  S. Long,et al.  Review Tansley Review , 2022 .

[93]  R. Furbank,et al.  The C4 pathway: an efficient CO2 pump , 2004, Photosynthesis Research.

[94]  Heather McGraw,et al.  Human Alteration of the Global Nitrogen Cycle , 2004 .

[95]  R. Furbank,et al.  The C(4) pathway: an efficient CO(2) pump. , 2003, Photosynthesis research.

[96]  Robert W. Howarth,et al.  Nitrogen limitation on land and in the sea: How can it occur? , 1991 .

[97]  C. Brooks Climatic Change , 1913, Nature.