Comparison of model estimates of the effects of aviation emissions on atmospheric ozone and methane
暂无分享,去创建一个
Mark Z. Jacobson | Andrei P. Sokolov | Nadine Unger | Guy P. Brasseur | Donald J. Wuebbles | Steven R.H. Barrett | Sebastian D. Eastham | Hongyan Dang | Arezoo Khodayari | Henry B. Selkirk | G. Brasseur | S. Eastham | N. Unger | D. Wuebbles | M. Jacobson | A. Sokolov | H. Selkirk | S. Olsen | Seth Olsen | H. Dang | S. Barrett | Arezoo Khodayari
[1] J. Lamarque,et al. Multimodel ensemble simulations of present-day and near-future tropospheric ozone , 2006 .
[2] J. Penner,et al. Aviation and the Global Atmosphere , 1999 .
[3] Keith P. Shine,et al. Impact of perturbations to nitrogen oxide emissions from global aviation , 2008 .
[4] Donald J. Wuebbles,et al. Radiative Forcing of Climate Changes in the Vertical Distribution of Ozone , 1990 .
[5] Volker Grewe,et al. On the attribution of contributions of atmospheric trace gases to emissions in atmospheric model applications , 2010 .
[6] Xin-Zhong Liang,et al. Climatic forcing of nitrogen oxides through changes in tropospheric ozone and methane; global 3D model studies , 1999 .
[7] Bethan Owen,et al. Comparison of global 3-D aviation emissions datasets , 2012 .
[8] M Z Jacobson,et al. The effects of aircraft on climate and pollution. Part II: 20-year impacts of exhaust from all commercial aircraft worldwide treated individually at the subgrid scale. , 2013, Faraday discussions.
[9] E. Dlugokencky,et al. Atmospheric chemistry and greenhouse gases , 2001 .
[10] Sanjiva K. Lele,et al. The effects of aircraft on climate and pollution. Part I: Numerical methods for treating the subgrid evolution of discrete size- and composition-resolved contrails from all commercial flights worldwide , 2011, J. Comput. Phys..
[11] P. J. Rasch,et al. CAM-chem: description and evaluation of interactive atmospheric chemistry in CESM , 2011 .
[12] Ralph Iovinelli. Aviation environmental design tool , 2011, ICNS 2011.
[13] A. Wong,et al. Generation and maintenance of pore pressure excess in a dehydrating system , 1997 .
[14] Anu Vedantham,et al. Aviation and the Global Atmosphere: A Special Report of IPCC Working Groups I and III , 1999 .
[15] O. Wild,et al. Excitation of the primary tropospheric chemical mode in a global three-dimensional model , 2000 .
[16] Robert Sausen,et al. Impact of aircraft NOx emissions. Part 1: Interactively coupled climate-chemistry simulations and sensitivities to climate-chemistry feedback, lightning and model resolution , 2002 .
[17] Richard G. Derwent,et al. Does the location of aircraft nitrogen oxide emissions affect their climate impact? , 2009 .
[18] Mark Z. Jacobson,et al. Analysis of emission data from global commercial aviation: 2004 and 2006 , 2010 .
[19] Peter Hollingsworth,et al. Aviation Environmental Design Tool (AEDT) System Architecture , 2007 .
[20] Andrew Macintosh,et al. International aviation emissions to 2025: Can emissions be stabilised without restricting demand? , 2008, Energy Policy.
[21] Michael J. Prather,et al. Uncertainties in climate assessment for the case of aviation NO , 2011, Proceedings of the National Academy of Sciences.
[22] Robert Sausen,et al. Transport impacts on atmosphere and climate , 2010 .
[23] Nadine Unger,et al. Simulations of preindustrial, present-day, and 2100 conditions in the NASA GISS composition and climate model G-PUCCINI , 2006 .
[24] M. Gauss,et al. Impact of aircraft NO x emissions on the atmosphere – tradeoffs to reduce the impact , 2005 .
[25] J. Lamarque,et al. CAM-chem: description and evaluation of interactive atmospheric chemistry in the Community Earth System Model , 2012 .
[26] Piers M. Forster,et al. Radiative forcing and temperature trends from stratospheric ozone changes , 1997 .
[27] O. Edenhofer,et al. Intergovernmental Panel on Climate Change (IPCC) , 2013 .
[28] J. Pyle,et al. Latitudinal variation of the effect of aviation NOx emissions on atmospheric ozone and methane and related climate metrics , 2013 .
[29] Richard Neale,et al. Toward a Minimal Representation of Aerosols in Climate Models: Description and Evaluation in the Community Atmosphere Model CAM5 , 2012 .
[30] Robert Sausen,et al. European scientific assessment of the atmospheric effects of aircraft emissions , 1998 .
[31] David S. Lee,et al. Transport impacts on atmosphere and climate: Aviation , 2009, Atmospheric Environment.
[32] Jens Borken-Kleefeld,et al. Radiative forcing due to changes in ozone and methane caused by the transport sector , 2011 .
[33] T. Berntsen,et al. Climatic effects of NOx emissions through changes in tropospheric O3 and CH4: A global 3D model study , 1997 .
[34] Jens Borken-Kleefeld,et al. The impact of traffic emissions on atmospheric ozone and OH: results from QUANTIFY , 2008 .
[35] Michael J. Prather,et al. Lifetimes and eigenstates in atmospheric chemistry , 1994 .
[36] T. Berntsen,et al. Future impact of non-land based traffic emissions on atmospheric ozone and OH – an optimistic scenario and a possible mitigation strategy , 2011 .
[37] Richard G. Derwent,et al. Radiative forcing from aircraft NOx emissions: Mechanisms and seasonal dependence , 2004 .
[38] Sergey Paltsev,et al. MIT Integrated Global System Model (IGSM) Version 2: Model Description and Baseline Evaluation , 2005 .
[39] J. Edmonds,et al. RCP4.5: a pathway for stabilization of radiative forcing by 2100 , 2011 .
[40] A. Thomson,et al. The representative concentration pathways: an overview , 2011 .