On the Linearity of Local and Regional Temperature Changes from 1.5°C to 2°C of Global Warming

Given the Paris Agreement it is imperative there is greater understanding of the consequences of limiting global warming to the target 1.5° and 2°C levels above preindustrial conditions. It is challenging to quantify changes across a small increment of global warming, so a pattern-scaling approach may be considered. Here we investigate the validity of such an approach by comprehensively examining how well local temperatures and warming trends in a 1.5°C world predict local temperatures at global warming of 2°C. Ensembles of transient coupled climate simulations from multiple models under different scenarios were compared and individual model responses were analyzed. For many places, the multimodel forced response of seasonal-average temperatures is approximately linear with global warming between 1.5° and 2°C. However, individual model results vary and large contributions from nonlinear changes in unforced variability or the forced response cannot be ruled out. In some regions, such as East Asia, models simulate substantially greater warming than is expected from linear scaling. Examining East Asia during boreal summer, we find that increased warming in the simulated 2°C world relative to scaling up from 1.5°C is related to reduced anthropogenic aerosol emissions. Our findings suggest that, where forcings other than those due to greenhouse gas emissions change, the warming experienced in a 1.5°C world is a poor predictor for local climate at 2°C of global warming. In addition to the analysis of the linearity in the forced climate change signal, we find that natural variability remains a substantial contribution to uncertainty at these low-warming targets.

[1]  C. Tebaldi,et al.  Evaluating the accuracy of climate change pattern emulation for low warming targets , 2018 .

[2]  R. Wood,et al.  An anatomy of the projected North Atlantic warming hole in CMIP5 models , 2018, Climate Dynamics.

[3]  E. Fischer,et al.  Will Half a Degree Make a Difference? Robust Projections of Indices of Mean and Extreme Climate in Europe Under 1.5°C, 2°C, and 3°C Global Warming , 2017 .

[4]  D. Karoly,et al.  Climate extremes in Europe at 1.5 and 2 degrees of global warming , 2017 .

[5]  W. G. Strand,et al.  Community climate simulations to assess avoided impacts in 1.5 and 2 °C futures , 2017 .

[6]  J. Smerdon,et al.  Projected drought risk in 1.5°C and 2°C warmer climates , 2017 .

[7]  D. Karoly,et al.  Australian climate extremes at 1.5 °C and 2 °C of global warming , 2017 .

[8]  C. Miao,et al.  Unraveling anthropogenic influence on the changing risk of heat waves in China , 2017 .

[9]  Xiaoye Zhang,et al.  Scenario dependence of future changes in climate extremes under 1.5 °C and 2 °C global warming , 2017, Scientific Reports.

[10]  A. King,et al.  Evolution of mean, variance and extremes in 21st century temperatures , 2017 .

[11]  J. Rogelj,et al.  Characterizing half‐a‐degree difference: a review of methods for identifying regional climate responses to global warming targets , 2017 .

[12]  Michael F. Wehner,et al.  Half a degree additional warming, prognosis and projected impacts (HAPPI): background and experimental design , 2017 .

[13]  D. Stone,et al.  Attribution of the July–August 2013 heat event in Central and Eastern China to anthropogenic greenhouse gas emissions , 2017 .

[14]  G. Hegerl,et al.  Summer heat waves over Eastern China: dynamical processes and trend attribution , 2017 .

[15]  P. Good,et al.  Large differences in regional precipitation change between a first and second 2 K of global warming , 2016, Nature Communications.

[16]  R. Betts,et al.  Realizing the impacts of a 1.5 °C warmer world , 2016 .

[17]  S. Seneviratne,et al.  Allowable CO2 emissions based on regional and impact-related climate targets , 2016, Nature.

[18]  E. Fischer,et al.  A scientific critique of the two-degree climate change target , 2016 .

[19]  J. Lamarque,et al.  The importance of aerosol scenarios in projections of future heat extremes , 2018, Climatic Change.

[20]  Daniel M. Mitchell,et al.  Attributing human mortality during extreme heat waves to anthropogenic climate change , 2015 .

[21]  E. Fischer,et al.  Differential climate impacts for policy-relevant limits to global warming: the case of 1.5 °C and 2 °C , 2015 .

[22]  E. Fischer,et al.  The timing of anthropogenic emergence in simulated climate extremes , 2015 .

[23]  Reto Knutti,et al.  Improved pattern scaling approaches for the use in climate impact studies , 2015 .

[24]  D. Karoly,et al.  Attribution of the record high Central England temperature of 2014 to anthropogenic influences , 2015 .

[25]  Jason Lowe,et al.  Corrigendum: Nonlinear regional warming with increasing CO 2 concentrations , 2015 .

[26]  F. Zwiers,et al.  Rapid increase in the risk of extreme summer heat in Eastern China , 2014 .

[27]  P. Jones,et al.  Updated high‐resolution grids of monthly climatic observations – the CRU TS3.10 Dataset , 2014 .

[28]  Claudia Tebaldi,et al.  Pattern scaling: Its strengths and limitations, and an update on the latest model simulations , 2014, Climatic Change.

[29]  M. Holland,et al.  Near-term climate change:Projections and predictability , 2014 .

[30]  Liping Zhang,et al.  Multidecadal North Atlantic sea surface temperature and Atlantic meridional overturning circulation variability in CMIP5 historical simulations , 2013 .

[31]  D. Karoly,et al.  Anthropogenic contributions to Australia's record summer temperatures of 2013 , 2013 .

[32]  P. J. Young,et al.  Long‐term ozone changes and associated climate impacts in CMIP5 simulations , 2013 .

[33]  C. Tebaldi,et al.  Long-term Climate Change: Projections, Commitments and Irreversibility , 2013 .

[34]  Karl E. Taylor,et al.  An overview of CMIP5 and the experiment design , 2012 .

[35]  E. Stehfest,et al.  Harmonization of land-use scenarios for the period 1500–2100: 600 years of global gridded annual land-use transitions, wood harvest, and resulting secondary lands , 2011 .

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

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

[38]  J. Thepaut,et al.  The ERA‐Interim reanalysis: configuration and performance of the data assimilation system , 2011 .

[39]  G. Hegerl,et al.  Human contribution to more-intense precipitation extremes , 2011, Nature.

[40]  C. Deser,et al.  Uncertainty in climate change projections: the role of internal variability , 2012, Climate Dynamics.

[41]  N. Gillett,et al.  Attribution of anthropogenic influence on seasonal sea level pressure , 2009 .

[42]  E. Hawkins,et al.  The Potential to Narrow Uncertainty in Regional Climate Predictions , 2009 .

[43]  F. Giorgi,et al.  Time of emergence (TOE) of GHG‐forced precipitation change hot‐spots , 2009 .

[44]  B. Soden,et al.  Robust Responses of the Hydrological Cycle to Global Warming , 2006 .

[45]  G. Meehl,et al.  Contributions of external forcings to Southern Annular Mode trends , 2006 .

[46]  R. Kinnersley,et al.  When smoke gets in our eyes: the multiple impacts of atmospheric black carbon on climate, air quality and health. , 2006, Environment international.

[47]  Paul J. Kushner,et al.  Southern Hemisphere Atmospheric Circulation Response to Global Warming , 2001 .