Evaluating the climate and air quality impacts of short-lived pollutants

This paper presents a summary of the work done within the European Union's Seventh Framework Programme project ECLIPSE (Evaluating the Climate and Air Quality Impacts of Short-Lived Pollutants). ECLIPSE had a unique systematic concept for designing a realistic and effective mitigation scenario...

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Published in:Atmospheric Chemistry and Physics
Main Authors: Stohl, A., Aamaas, B., Amann, M., Baker, L. H., Bellouin, N., Berntsen, T. K., Boucher, O., Cherian, R., Collins, W., Daskalakis, N., Dusinska, M., Eckhardt, S., Fuglestvedt, J. S., Harju, M., Heyes, C., Hodnebrog, O., Hao, J., Im, U., Kanakidou, M., Klimont, Z., Kupiainen, K., Law, K. S., Lund, M. T., Maas, R., MacIntosh, C. R., Myhre, G., Myriokefalitakis, S., Olivie, D., Quaas, J., Quennehen, B., Raut, J.C., Rumbold, S. T., Samset, B. H., Schulz, M., Seland, O., Shine, K. P., Skeie, R. B., Wang, S., Yttri, K. E., Zhu, T.
Other Authors: Stohl, A (reprint author), NILU Norwegian Inst Air Res, Kjeller, Norway., NILU Norwegian Inst Air Res, Kjeller, Norway., Ctr Int Climate & Environm Res Oslo, Oslo, Norway., Int Inst Appl Syst Anal, A-2361 Laxenburg, Austria., Univ Reading, Dept Meteorol, Reading, Berks, England., Univ Paris 06, CNRS, LATMOS, Paris, France., Univ Leipzig, Inst Meteorol, D-04109 Leipzig, Germany., Met Off Hadley Ctr, Exeter, Devon, England., Univ Crete, Dept Chem, Environm Chem Proc Lab, Iraklion, Crete, Greece., ICE HT, FORTH, Patras, Greece., Tsinghua Univ, Sch Environm, Beijing 100084, Peoples R China., Univ Paris 06, Univ Paris 04, Univ Versailles St Quentin, CNRS INSU,LATMOS IPSL, Paris, France., RIVM Natl Inst Publ Hlth & Environm, Bilthoven, Netherlands., Norwegian Meteorol Inst, Oslo, Norway., Peking Univ, Coll Environm Sci & Engn, State Key Lab Environm Simulat & Pollut Control, Beijing 100871, Peoples R China.
Format: Journal/Newspaper
Language:English
Published: ATMOSPHERIC CHEMISTRY AND PHYSICS 2015
Subjects:
DISPERSION MODEL FLEXPART
BLACK-CARBON MITIGATION
FORCING TIME-SERIES
NEAR-TERM
GREENHOUSE GASES
TEMPERATURE-CHANGE
EMISSION CONTROLS
FIRE EMISSIONS
NOX EMISSIONS
AEROSOL
Arctic
black carbon
Sea ice
Online Access:https://hdl.handle.net/20.500.11897/421017
https://doi.org/10.5194/acp-15-10529-2015
id ftpekinguniv:oai:localhost:20.500.11897/421017
record_format openpolar
institution Open Polar
collection Peking University Institutional Repository (PKU IR)
op_collection_id ftpekinguniv
language English
topic DISPERSION MODEL FLEXPART
BLACK-CARBON MITIGATION
FORCING TIME-SERIES
NEAR-TERM
GREENHOUSE GASES
TEMPERATURE-CHANGE
EMISSION CONTROLS
FIRE EMISSIONS
NOX EMISSIONS
AEROSOL
spellingShingle DISPERSION MODEL FLEXPART
BLACK-CARBON MITIGATION
FORCING TIME-SERIES
NEAR-TERM
GREENHOUSE GASES
TEMPERATURE-CHANGE
EMISSION CONTROLS
FIRE EMISSIONS
NOX EMISSIONS
AEROSOL
Stohl, A.
Aamaas, B.
Amann, M.
Baker, L. H.
Bellouin, N.
Berntsen, T. K.
Boucher, O.
Cherian, R.
Collins, W.
Daskalakis, N.
Dusinska, M.
Eckhardt, S.
Fuglestvedt, J. S.
Harju, M.
Heyes, C.
Hodnebrog, O.
Hao, J.
Im, U.
Kanakidou, M.
Klimont, Z.
Kupiainen, K.
Law, K. S.
Lund, M. T.
Maas, R.
MacIntosh, C. R.
Myhre, G.
Myriokefalitakis, S.
Olivie, D.
Quaas, J.
Quennehen, B.
Raut, J.C.
Rumbold, S. T.
Samset, B. H.
Schulz, M.
Seland, O.
Shine, K. P.
Skeie, R. B.
Wang, S.
Yttri, K. E.
Zhu, T.
Evaluating the climate and air quality impacts of short-lived pollutants
topic_facet DISPERSION MODEL FLEXPART
BLACK-CARBON MITIGATION
FORCING TIME-SERIES
NEAR-TERM
GREENHOUSE GASES
TEMPERATURE-CHANGE
EMISSION CONTROLS
FIRE EMISSIONS
NOX EMISSIONS
AEROSOL
description This paper presents a summary of the work done within the European Union's Seventh Framework Programme project ECLIPSE (Evaluating the Climate and Air Quality Impacts of Short-Lived Pollutants). ECLIPSE had a unique systematic concept for designing a realistic and effective mitigation scenario for short-lived climate pollutants (SLCPs; methane, aerosols and ozone, and their precursor species) and quantifying its climate and air quality impacts, and this paper presents the results in the context of this overarching strategy. The first step in ECLIPSE was to create a new emission inventory based on current legislation (CLE) for the recent past and until 2050. Substantial progress compared to previous work was made by including previously unaccounted types of sources such as flaring of gas associated with oil production, and wick lamps. These emission data were used for present-day reference simulations with four advanced Earth system models (ESMs) and six chemistry transport models (CTMs). The model simulations were compared with a variety of ground-based and satellite observational data sets from Asia, Europe and the Arctic. It was found that the models still underestimate the measured seasonality of aerosols in the Arctic but to a lesser extent than in previous studies. Problems likely related to the emissions were identified for northern Russia and India, in particular. To estimate the climate impacts of SLCPs, ECLIPSE followed two paths of research: the first path calculated radiative forcing (RF) values for a large matrix of SLCP species emissions, for different seasons and regions independently. Based on these RF calculations, the Global Temperature change Potential metric for a time horizon of 20 years (GTP(20)) was calculated for each SLCP emission type. This climate metric was then used in an integrated assessment model to identify all emission mitigation measures with a beneficial air quality and short-term (20-year) climate impact. These measures together defined a SLCP mitigation (MIT) scenario. Compared to CLE, the MIT scenario would reduce global methane (CH4) and black carbon (BC) emissions by about 50 and 80 %, respectively. For CH4, measures on shale gas production, waste management and coal mines were most important. For non-CH4 SLCPs, elimination of high-emitting vehicles and wick lamps, as well as reducing emissions from gas flaring, coal and biomass stoves, agricultural waste, solvents and diesel engines were most important. These measures lead to large reductions in calculated surface concentrations of ozone and particulate matter. We estimate that in the EU, the loss of statistical life expectancy due to air pollution was 7.5 months in 2010, which will be reduced to 5.2 months by 2030 in the CLE scenario. The MIT scenario would reduce this value by another 0.9 to 4.3 months. Substantially larger reductions due to the mitigation are found for China (1.8 months) and India (11-12 months). The climate metrics cannot fully quantify the climate response. Therefore, a second research path was taken. Transient climate ensemble simulations with the four ESMs were run for the CLE and MIT scenarios, to determine the climate impacts of the mitigation. In these simulations, the CLE scenario resulted in a surface temperature increase of 0.70 +/- 0.14 K between the years 2006 and 2050. For the decade 2041-2050, the warming was reduced by 0.22 +/- 0. 07 K in the MIT scenario, and this result was in almost exact agreement with the response calculated based on the emission metrics (reduced warming of 0.22 +/- 0.09 K). The metrics calculations suggest that non-CH4 SLCPs contribute similar to 22 % to this response and CH4 78 %. This could not be fully confirmed by the transient simulations, which attributed about 90 % of the temperature response to CH4 reductions. Attribution of the observed temperature response to non-CH4 SLCP emission reductions and BC specifically is hampered in the transient simulations by small forcing and co-emitted species of the emission basket chosen. Nevertheless, an important conclusion is that our mitigation basket as a whole would lead to clear benefits for both air quality and climate. The climate response from BC reductions in our study is smaller than reported previously, possibly because our study is one of the first to use fully coupled climate models, where unforced variability and sea ice responses cause relatively strong temperature fluctuations that may counteract (and, thus, mask) the impacts of small emission reductions. The temperature responses to the mitigation were generally stronger over the continents than over the oceans, and with a warming reduction of 0.44 K (0.39-0.49) K the largest over the Arctic. Our calculations suggest particularly beneficial climate responses in southern Europe, where surface warming was reduced by about 0.3 K and precipitation rates were increased by about 15 (6-21) mm yr(-1) (more than 4 % of total precipitation) from spring to autumn. Thus, the mitigation could help to alleviate expected future drought and water shortages in the Mediterranean area. We also report other important results of the ECLIPSE project. European Union [282688 - ECLIPSE]; Nordforsk SCI(E) ARTICLE ast@nilu.no 18 10529-10566 15
author2 Stohl, A (reprint author), NILU Norwegian Inst Air Res, Kjeller, Norway.
NILU Norwegian Inst Air Res, Kjeller, Norway.
Ctr Int Climate & Environm Res Oslo, Oslo, Norway.
Int Inst Appl Syst Anal, A-2361 Laxenburg, Austria.
Univ Reading, Dept Meteorol, Reading, Berks, England.
Univ Paris 06, CNRS, LATMOS, Paris, France.
Univ Leipzig, Inst Meteorol, D-04109 Leipzig, Germany.
Met Off Hadley Ctr, Exeter, Devon, England.
Univ Crete, Dept Chem, Environm Chem Proc Lab, Iraklion, Crete, Greece.
ICE HT, FORTH, Patras, Greece.
Tsinghua Univ, Sch Environm, Beijing 100084, Peoples R China.
Univ Paris 06, Univ Paris 04, Univ Versailles St Quentin, CNRS INSU,LATMOS IPSL, Paris, France.
RIVM Natl Inst Publ Hlth & Environm, Bilthoven, Netherlands.
Norwegian Meteorol Inst, Oslo, Norway.
Peking Univ, Coll Environm Sci & Engn, State Key Lab Environm Simulat & Pollut Control, Beijing 100871, Peoples R China.
format Journal/Newspaper
author Stohl, A.
Aamaas, B.
Amann, M.
Baker, L. H.
Bellouin, N.
Berntsen, T. K.
Boucher, O.
Cherian, R.
Collins, W.
Daskalakis, N.
Dusinska, M.
Eckhardt, S.
Fuglestvedt, J. S.
Harju, M.
Heyes, C.
Hodnebrog, O.
Hao, J.
Im, U.
Kanakidou, M.
Klimont, Z.
Kupiainen, K.
Law, K. S.
Lund, M. T.
Maas, R.
MacIntosh, C. R.
Myhre, G.
Myriokefalitakis, S.
Olivie, D.
Quaas, J.
Quennehen, B.
Raut, J.C.
Rumbold, S. T.
Samset, B. H.
Schulz, M.
Seland, O.
Shine, K. P.
Skeie, R. B.
Wang, S.
Yttri, K. E.
Zhu, T.
author_facet Stohl, A.
Aamaas, B.
Amann, M.
Baker, L. H.
Bellouin, N.
Berntsen, T. K.
Boucher, O.
Cherian, R.
Collins, W.
Daskalakis, N.
Dusinska, M.
Eckhardt, S.
Fuglestvedt, J. S.
Harju, M.
Heyes, C.
Hodnebrog, O.
Hao, J.
Im, U.
Kanakidou, M.
Klimont, Z.
Kupiainen, K.
Law, K. S.
Lund, M. T.
Maas, R.
MacIntosh, C. R.
Myhre, G.
Myriokefalitakis, S.
Olivie, D.
Quaas, J.
Quennehen, B.
Raut, J.C.
Rumbold, S. T.
Samset, B. H.
Schulz, M.
Seland, O.
Shine, K. P.
Skeie, R. B.
Wang, S.
Yttri, K. E.
Zhu, T.
author_sort Stohl, A.
title Evaluating the climate and air quality impacts of short-lived pollutants
title_short Evaluating the climate and air quality impacts of short-lived pollutants
title_full Evaluating the climate and air quality impacts of short-lived pollutants
title_fullStr Evaluating the climate and air quality impacts of short-lived pollutants
title_full_unstemmed Evaluating the climate and air quality impacts of short-lived pollutants
title_sort evaluating the climate and air quality impacts of short-lived pollutants
publisher ATMOSPHERIC CHEMISTRY AND PHYSICS
publishDate 2015
url https://hdl.handle.net/20.500.11897/421017
https://doi.org/10.5194/acp-15-10529-2015
geographic Arctic
geographic_facet Arctic
genre Arctic
black carbon
Sea ice
genre_facet Arctic
black carbon
Sea ice
op_source SCI
op_relation ATMOSPHERIC CHEMISTRY AND PHYSICS.2015,15,(18),10529-10566.
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doi:10.5194/acp-15-10529-2015
WOS:000362457400017
op_doi https://doi.org/20.500.11897/421017
https://doi.org/10.5194/acp-15-10529-2015
container_title Atmospheric Chemistry and Physics
container_volume 15
container_issue 18
container_start_page 10529
op_container_end_page 10566
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spelling ftpekinguniv:oai:localhost:20.500.11897/421017 2023-05-15T15:11:35+02:00 Evaluating the climate and air quality impacts of short-lived pollutants Stohl, A. Aamaas, B. Amann, M. Baker, L. H. Bellouin, N. Berntsen, T. K. Boucher, O. Cherian, R. Collins, W. Daskalakis, N. Dusinska, M. Eckhardt, S. Fuglestvedt, J. S. Harju, M. Heyes, C. Hodnebrog, O. Hao, J. Im, U. Kanakidou, M. Klimont, Z. Kupiainen, K. Law, K. S. Lund, M. T. Maas, R. MacIntosh, C. R. Myhre, G. Myriokefalitakis, S. Olivie, D. Quaas, J. Quennehen, B. Raut, J.C. Rumbold, S. T. Samset, B. H. Schulz, M. Seland, O. Shine, K. P. Skeie, R. B. Wang, S. Yttri, K. E. Zhu, T. Stohl, A (reprint author), NILU Norwegian Inst Air Res, Kjeller, Norway. NILU Norwegian Inst Air Res, Kjeller, Norway. Ctr Int Climate & Environm Res Oslo, Oslo, Norway. Int Inst Appl Syst Anal, A-2361 Laxenburg, Austria. Univ Reading, Dept Meteorol, Reading, Berks, England. Univ Paris 06, CNRS, LATMOS, Paris, France. Univ Leipzig, Inst Meteorol, D-04109 Leipzig, Germany. Met Off Hadley Ctr, Exeter, Devon, England. Univ Crete, Dept Chem, Environm Chem Proc Lab, Iraklion, Crete, Greece. ICE HT, FORTH, Patras, Greece. Tsinghua Univ, Sch Environm, Beijing 100084, Peoples R China. Univ Paris 06, Univ Paris 04, Univ Versailles St Quentin, CNRS INSU,LATMOS IPSL, Paris, France. RIVM Natl Inst Publ Hlth & Environm, Bilthoven, Netherlands. Norwegian Meteorol Inst, Oslo, Norway. Peking Univ, Coll Environm Sci & Engn, State Key Lab Environm Simulat & Pollut Control, Beijing 100871, Peoples R China. 2015 https://hdl.handle.net/20.500.11897/421017 https://doi.org/10.5194/acp-15-10529-2015 en eng ATMOSPHERIC CHEMISTRY AND PHYSICS ATMOSPHERIC CHEMISTRY AND PHYSICS.2015,15,(18),10529-10566. 1314710 1680-7316 http://hdl.handle.net/20.500.11897/421017 1680-7324 doi:10.5194/acp-15-10529-2015 WOS:000362457400017 SCI DISPERSION MODEL FLEXPART BLACK-CARBON MITIGATION FORCING TIME-SERIES NEAR-TERM GREENHOUSE GASES TEMPERATURE-CHANGE EMISSION CONTROLS FIRE EMISSIONS NOX EMISSIONS AEROSOL Journal 2015 ftpekinguniv https://doi.org/20.500.11897/421017 https://doi.org/10.5194/acp-15-10529-2015 2021-08-01T10:38:50Z This paper presents a summary of the work done within the European Union's Seventh Framework Programme project ECLIPSE (Evaluating the Climate and Air Quality Impacts of Short-Lived Pollutants). ECLIPSE had a unique systematic concept for designing a realistic and effective mitigation scenario for short-lived climate pollutants (SLCPs; methane, aerosols and ozone, and their precursor species) and quantifying its climate and air quality impacts, and this paper presents the results in the context of this overarching strategy. The first step in ECLIPSE was to create a new emission inventory based on current legislation (CLE) for the recent past and until 2050. Substantial progress compared to previous work was made by including previously unaccounted types of sources such as flaring of gas associated with oil production, and wick lamps. These emission data were used for present-day reference simulations with four advanced Earth system models (ESMs) and six chemistry transport models (CTMs). The model simulations were compared with a variety of ground-based and satellite observational data sets from Asia, Europe and the Arctic. It was found that the models still underestimate the measured seasonality of aerosols in the Arctic but to a lesser extent than in previous studies. Problems likely related to the emissions were identified for northern Russia and India, in particular. To estimate the climate impacts of SLCPs, ECLIPSE followed two paths of research: the first path calculated radiative forcing (RF) values for a large matrix of SLCP species emissions, for different seasons and regions independently. Based on these RF calculations, the Global Temperature change Potential metric for a time horizon of 20 years (GTP(20)) was calculated for each SLCP emission type. This climate metric was then used in an integrated assessment model to identify all emission mitigation measures with a beneficial air quality and short-term (20-year) climate impact. These measures together defined a SLCP mitigation (MIT) scenario. Compared to CLE, the MIT scenario would reduce global methane (CH4) and black carbon (BC) emissions by about 50 and 80 %, respectively. For CH4, measures on shale gas production, waste management and coal mines were most important. For non-CH4 SLCPs, elimination of high-emitting vehicles and wick lamps, as well as reducing emissions from gas flaring, coal and biomass stoves, agricultural waste, solvents and diesel engines were most important. These measures lead to large reductions in calculated surface concentrations of ozone and particulate matter. We estimate that in the EU, the loss of statistical life expectancy due to air pollution was 7.5 months in 2010, which will be reduced to 5.2 months by 2030 in the CLE scenario. The MIT scenario would reduce this value by another 0.9 to 4.3 months. Substantially larger reductions due to the mitigation are found for China (1.8 months) and India (11-12 months). The climate metrics cannot fully quantify the climate response. Therefore, a second research path was taken. Transient climate ensemble simulations with the four ESMs were run for the CLE and MIT scenarios, to determine the climate impacts of the mitigation. In these simulations, the CLE scenario resulted in a surface temperature increase of 0.70 +/- 0.14 K between the years 2006 and 2050. For the decade 2041-2050, the warming was reduced by 0.22 +/- 0. 07 K in the MIT scenario, and this result was in almost exact agreement with the response calculated based on the emission metrics (reduced warming of 0.22 +/- 0.09 K). The metrics calculations suggest that non-CH4 SLCPs contribute similar to 22 % to this response and CH4 78 %. This could not be fully confirmed by the transient simulations, which attributed about 90 % of the temperature response to CH4 reductions. Attribution of the observed temperature response to non-CH4 SLCP emission reductions and BC specifically is hampered in the transient simulations by small forcing and co-emitted species of the emission basket chosen. Nevertheless, an important conclusion is that our mitigation basket as a whole would lead to clear benefits for both air quality and climate. The climate response from BC reductions in our study is smaller than reported previously, possibly because our study is one of the first to use fully coupled climate models, where unforced variability and sea ice responses cause relatively strong temperature fluctuations that may counteract (and, thus, mask) the impacts of small emission reductions. The temperature responses to the mitigation were generally stronger over the continents than over the oceans, and with a warming reduction of 0.44 K (0.39-0.49) K the largest over the Arctic. Our calculations suggest particularly beneficial climate responses in southern Europe, where surface warming was reduced by about 0.3 K and precipitation rates were increased by about 15 (6-21) mm yr(-1) (more than 4 % of total precipitation) from spring to autumn. Thus, the mitigation could help to alleviate expected future drought and water shortages in the Mediterranean area. We also report other important results of the ECLIPSE project. European Union [282688 - ECLIPSE]; Nordforsk SCI(E) ARTICLE ast@nilu.no 18 10529-10566 15 Journal/Newspaper Arctic black carbon Sea ice Peking University Institutional Repository (PKU IR) Arctic Atmospheric Chemistry and Physics 15 18 10529 10566

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