Mitigating the Climate Forcing of Aircraft Contrails by Small-Scale Diversions and Technology Adoption.

The climate forcing of contrails and induced-cirrus cloudiness is thought to be comparable to the cumulative impacts of aviation CO2 emissions. This paper estimates the impact of aviation contrails on climate forcing for flight track data in Japanese airspace and propagates uncertainties arising from meteorology and aircraft black carbon (BC) particle number emissions. Uncertainties in the contrail age, coverage, optical properties, radiative forcing, and energy forcing (EF) from individual flights can be 2 orders of magnitude larger than the fleet-average values. Only 2.2% [2.0, 2.5%] of flights contribute to 80% of the contrail EF in this region. A small-scale strategy of selectively diverting 1.7% of the fleet could reduce the contrail EF by up to 59.3% [52.4, 65.6%], with only a 0.014% [0.010, 0.017%] increase in total fuel consumption and CO2 emissions. A low-risk strategy of diverting flights only if there is no fuel penalty, thereby avoiding additional long-lived CO2 emissions, would reduce contrail EF by 20.0% [17.4, 23.0%]. In the longer term, widespread use of new engine combustor technology, which reduces BC particle emissions, could achieve a 68.8% [45.2, 82.1%] reduction in the contrail EF. A combination of both interventions could reduce the contrail EF by 91.8% [88.6, 95.8%].

[1]  Mark H Lowenberg,et al.  An aircraft performance model implementation for the estimation of global and regional commercial aviation fuel burn and emissions , 2015 .

[2]  B. Mayer,et al.  A Parametric Radiative Forcing Model for Contrail Cirrus , 2012 .

[3]  Hermann Mannstein,et al.  Aircraft induced contrail cirrus over Europe , 2005 .

[4]  Mark P. Johnson,et al.  Particle Emission Characteristics of a Gas Turbine with a Double Annular Combustor , 2015 .

[5]  Antonio Filippone Assessment of Aircraft Contrails Avoidance Strategies , 2015 .

[6]  D. Lewellen Persistent Contrails and Contrail Cirrus. Part II: Full Lifetime Behavior , 2014 .

[7]  S. Barrett,et al.  Impact of biofuels on contrail warming , 2017 .

[8]  David S. Lee,et al.  Transport impacts on atmosphere and climate: Aviation , 2009, Atmospheric Environment.

[9]  Simon Unterstrasser,et al.  Study of contrail microphysics in the vortex phase with a Lagrangian particle tracking model , 2010 .

[10]  Ulrich Schumann,et al.  Potential to reduce the climate impact of aviation by flight level changes , 2011 .

[11]  Marc E.J. Stettler,et al.  Rapid estimation of global civil aviation emissions with uncertainty quantification , 2013 .

[12]  Reinhold Busen,et al.  Influence of fuel sulfur on the composition of aircraft exhaust plumes: The experiments SULFUR 1–7 , 2002 .

[13]  B. Kärcher,et al.  Global radiative forcing from contrail cirrus , 2011 .

[14]  Robert B. Noland,et al.  Variability of Contrail Formation Conditions and the Implications for Policies to Reduce the Climate Impacts of Aviation , 2005 .

[15]  U. Schumann A contrail cirrus prediction model , 2011 .

[16]  Ian G. Enting,et al.  Carbon dioxide and climate impulse response functions for the computation of greenhouse gas metrics:a multi-model analysis , 2012 .

[17]  Lisa Bock,et al.  Mitigating the contrail cirrus climate impact by reducing aircraft soot number emissions , 2018, npj Climate and Atmospheric Science.

[18]  M. Jacobson,et al.  Parameterization of subgrid plume dilution for use in large-scale atmospheric simulations , 2010 .

[19]  Ulrich Schumann,et al.  Formation, properties and climatic effects of contrails , 2005 .

[20]  Mark Z. Jacobson,et al.  Analysis of emission data from global commercial aviation: 2004 and 2006 , 2010 .

[21]  B. Kärcher Formation and radiative forcing of contrail cirrus , 2018, Nature Communications.

[22]  B. Mayer,et al.  Sensitivity of surface temperature to radiative forcing by contrail cirrus in a radiative-mixing model , 2017 .

[23]  Joseph Zelina,et al.  Predictive Model Development for Aviation Black Carbon Mass Emissions from Alternative and Conventional Fuels at Ground and Cruise. , 2016, Environmental science & technology.

[24]  Akinori Harada,et al.  Accuracy Evaluation of an Aircraft Performance Model with Airliner Flight Data , 2013 .

[25]  Marc E.J. Stettler,et al.  Air quality and public health impacts of UK airports. Part I: Emissions , 2011 .

[26]  Marc E.J. Stettler,et al.  Global civil aviation black carbon emissions. , 2013, Environmental science & technology.

[27]  Klaus Gierens,et al.  A note on how to avoid contrail cirrus , 2005 .

[28]  J. Penner,et al.  Dehydration effects from contrails in a coupled contrail–climate model , 2015 .

[29]  B. Mayer,et al.  Contrails: Visible Aviation Induced Climate Impact , 2012 .

[30]  Contrail cirrus radiative forcing for future air traffic , 2019, Atmospheric Chemistry and Physics.

[31]  W. S. Lewellen,et al.  The Effects of Aircraft Wake Dynamics on Contrail Development , 2001 .

[32]  V. Freudenthaler,et al.  Properties of individual contrails: A compilation of observations and some comparisons , 2016 .

[33]  Brian J. Hoskins,et al.  A simple framework for assessing the trade-off between the climate impact of aviation carbon dioxide emissions and contrails for a single flight , 2014 .

[34]  U. Schumann,et al.  On the Life Cycle of Individual Contrails and Contrail Cirrus , 2017 .

[35]  Ralph J. Iovinelli,et al.  SCOPE11 Method for Estimating Aircraft Black Carbon Mass and Particle Number Emissions. , 2019, Environmental science & technology.

[36]  P. Forster,et al.  Intercomparison of radiative forcing calculations of stratospheric water vapour and contrails , 2009 .

[37]  Richard C. Miake-Lye,et al.  Environmental conditions required for contrail formation and persistence , 1998 .

[38]  Vincent Mouillet,et al.  BADA: An advanced aircraft performance model for present and future ATM systems , 2010 .

[39]  Anthony P. Brown,et al.  Biofuel blending reduces particle emissions from aircraft engines at cruise conditions , 2017, Nature.

[40]  R. Sausen,et al.  Why radiative forcing might fail as a predictor of climate change , 2005 .

[41]  H. Mannstein,et al.  Contrail life cycle and properties from 1 year of MSG/SEVIRI rapid-scan images , 2015 .

[42]  Bernd Kärcher,et al.  The importance of contrail ice formation for mitigating the climate impact of aviation , 2016 .

[43]  Nicola Stuber,et al.  The importance of the diurnal and annual cycle of air traffic for contrail radiative forcing , 2006, Nature.

[44]  D. Hagen,et al.  Measurement of Aircraft Engine Non-Volatile PM Emissions: Results of the Aviation-Particle Regulatory Instrumentation Demonstration Experiment (A-PRIDE) 4 Campaign , 2015 .

[45]  Ulrich Schumann,et al.  Contrail ice particles in aircraft wakes and their climatic importance , 2013 .

[46]  Klaus Gierens,et al.  Ice supersaturation in the tropopause region over Lindenberg, Germany , 2003 .

[47]  J. Fuglestvedt,et al.  Feasibility of climate-optimized air traffic routing for trans-Atlantic flights , 2017 .

[48]  Robert Sausen,et al.  On contrail climate sensitivity , 2005 .

[49]  宮沢 与和,et al.  CARATS Open Dataの精度に関する一検討 , 2016 .

[50]  U. Schumann,et al.  Aviation‐induced cirrus and radiation changes at diurnal timescales , 2013 .

[51]  Ulrich Schumann,et al.  Aircraft type influence on contrail properties , 2013 .

[52]  Yixiang Lim,et al.  Optimal aircraft trajectories to minimize the radiative impact of contrails and CO2 , 2017 .

[53]  U. Schumann Über Bedingungen zur Bildung von Kondensstreifen aus Flugzeugabgasen , 1996 .