Aircraft routing with minimal climate impact: The REACT4C climate cost function modelling approach (V1.0)

In addition to CO2, the climate impact of aviation is strongly influenced by non-CO2 emissions, such as nitrogen oxides, influencing ozone and methane, and water vapour, which can lead to the formation of persistent contrails in ice supersaturated regions. Because these non-CO2 emission effects are...

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Published in:Geoscientific Model Development
Main Authors: Grewe, Volker, Frömming, Christine, Matthes, Sigrun, Brinkop, Sabine, Ponater, Michael, Dietmüller, Simone, Jöckel, Patrick, Garny, Hella, Tsati, Eleni, Dahlmann, Katrin, Sovde, O.A., Fuglestvedt, J.S., Berntsen, T., Shine, K.P., Irvine, Emma A., Champougny, T., Hullah, P.
Format: Other Non-Article Part of Journal/Newspaper
Language:unknown
Published: Copernicus Publications 2014
Subjects:
Institut für Physik der Atmosphäre
Dynamik der Atmosphäre
North Atlantic
Online Access:https://elib.dlr.de/86884/
http://www.geosci-model-dev.net/7/175/2014/gmd-7-175-2014.pdf
id ftdlr:oai:elib.dlr.de:86884
record_format openpolar
spelling ftdlr:oai:elib.dlr.de:86884 2023-05-15T17:37:02+02:00 Aircraft routing with minimal climate impact: The REACT4C climate cost function modelling approach (V1.0) Grewe, Volker Frömming, Christine Matthes, Sigrun Brinkop, Sabine Ponater, Michael Dietmüller, Simone Jöckel, Patrick Garny, Hella Tsati, Eleni Dahlmann, Katrin Sovde, O.A. Fuglestvedt, J.S. Berntsen, T. Shine, K.P. Irvine, Emma A. Champougny, T. Hullah, P. 2014 https://elib.dlr.de/86884/ http://www.geosci-model-dev.net/7/175/2014/gmd-7-175-2014.pdf unknown Copernicus Publications Grewe, Volker und Frömming, Christine und Matthes, Sigrun und Brinkop, Sabine und Ponater, Michael und Dietmüller, Simone und Jöckel, Patrick und Garny, Hella und Tsati, Eleni und Dahlmann, Katrin und Sovde, O.A. und Fuglestvedt, J.S. und Berntsen, T. und Shine, K.P. und Irvine, Emma A. und Champougny, T. und Hullah, P. (2014) Aircraft routing with minimal climate impact: The REACT4C climate cost function modelling approach (V1.0). Geoscientific Model Development, Seiten 175-201. Copernicus Publications. DOI:10.5194/gmd-7-175-2014 <https://doi.org/10.5194/gmd-7-175-2014> ISSN 1991-959X Institut für Physik der Atmosphäre Dynamik der Atmosphäre Zeitschriftenbeitrag PeerReviewed 2014 ftdlr https://doi.org/10.5194/gmd-7-175-2014 2019-05-05T22:52:59Z In addition to CO2, the climate impact of aviation is strongly influenced by non-CO2 emissions, such as nitrogen oxides, influencing ozone and methane, and water vapour, which can lead to the formation of persistent contrails in ice supersaturated regions. Because these non-CO2 emission effects are characterised by a short lifetime, their climate impact largely depends on emission location and time, i.e. emissions in certain locations (or times) can lead to a greater climate impact (even on the global average) than the same emission in other locations (or times). Avoiding these climate sensitive regions might thus be beneficial to climate. Here, we describe a modelling chain for investigating this climate impact mitigation option. It forms a multi-step modelling approach, starting with the simulation of the fate of emissions released at a certain location and time (time-region grid points). This is performed with the chemistry–climate model EMAC, extended by the two submodels AIRTRAC (V1.0) and CONTRAIL (V1.0), which describe the contribution of emissions to the composition of the atmosphere and to contrail formation, respectively. The impact of emissions from the large number of time-region grid points is efficiently calculated by applying a Lagrangian scheme. EMAC also includes the calculation of radiative impacts, which are, in a second step, the input to climate metric formulas describing the global climate impact of the mission at each time-region grid point. The result of the modelling chain comprises a four dimensional dataset in space and time, which we call climate cost functions, and which describe at each grid point and each point in time, the global climate impact of an emission. In a third step, these climate cost functions are used in an air traffic simulator (SAAM), coupled to an emission tool (AEM) to optimise aircraft trajectories for the North Atlantic region. Here, we describe the details of this new modelling approach and show some example results. A number of sensitivity analyses are performed to motivate the settings of individual parameters. A stepwise sanity check of the results of the modelling chain is undertaken to demonstrate the plausibility of the climate cost functions. Other Non-Article Part of Journal/Newspaper North Atlantic German Aerospace Center: elib - DLR electronic library Geoscientific Model Development 7 1 175 201
institution Open Polar
collection German Aerospace Center: elib - DLR electronic library
op_collection_id ftdlr
language unknown
topic Institut für Physik der Atmosphäre
Dynamik der Atmosphäre
spellingShingle Institut für Physik der Atmosphäre
Dynamik der Atmosphäre
Grewe, Volker
Frömming, Christine
Matthes, Sigrun
Brinkop, Sabine
Ponater, Michael
Dietmüller, Simone
Jöckel, Patrick
Garny, Hella
Tsati, Eleni
Dahlmann, Katrin
Sovde, O.A.
Fuglestvedt, J.S.
Berntsen, T.
Shine, K.P.
Irvine, Emma A.
Champougny, T.
Hullah, P.
Aircraft routing with minimal climate impact: The REACT4C climate cost function modelling approach (V1.0)
topic_facet Institut für Physik der Atmosphäre
Dynamik der Atmosphäre
description In addition to CO2, the climate impact of aviation is strongly influenced by non-CO2 emissions, such as nitrogen oxides, influencing ozone and methane, and water vapour, which can lead to the formation of persistent contrails in ice supersaturated regions. Because these non-CO2 emission effects are characterised by a short lifetime, their climate impact largely depends on emission location and time, i.e. emissions in certain locations (or times) can lead to a greater climate impact (even on the global average) than the same emission in other locations (or times). Avoiding these climate sensitive regions might thus be beneficial to climate. Here, we describe a modelling chain for investigating this climate impact mitigation option. It forms a multi-step modelling approach, starting with the simulation of the fate of emissions released at a certain location and time (time-region grid points). This is performed with the chemistry–climate model EMAC, extended by the two submodels AIRTRAC (V1.0) and CONTRAIL (V1.0), which describe the contribution of emissions to the composition of the atmosphere and to contrail formation, respectively. The impact of emissions from the large number of time-region grid points is efficiently calculated by applying a Lagrangian scheme. EMAC also includes the calculation of radiative impacts, which are, in a second step, the input to climate metric formulas describing the global climate impact of the mission at each time-region grid point. The result of the modelling chain comprises a four dimensional dataset in space and time, which we call climate cost functions, and which describe at each grid point and each point in time, the global climate impact of an emission. In a third step, these climate cost functions are used in an air traffic simulator (SAAM), coupled to an emission tool (AEM) to optimise aircraft trajectories for the North Atlantic region. Here, we describe the details of this new modelling approach and show some example results. A number of sensitivity analyses are performed to motivate the settings of individual parameters. A stepwise sanity check of the results of the modelling chain is undertaken to demonstrate the plausibility of the climate cost functions.
format Other Non-Article Part of Journal/Newspaper
author Grewe, Volker
Frömming, Christine
Matthes, Sigrun
Brinkop, Sabine
Ponater, Michael
Dietmüller, Simone
Jöckel, Patrick
Garny, Hella
Tsati, Eleni
Dahlmann, Katrin
Sovde, O.A.
Fuglestvedt, J.S.
Berntsen, T.
Shine, K.P.
Irvine, Emma A.
Champougny, T.
Hullah, P.
author_facet Grewe, Volker
Frömming, Christine
Matthes, Sigrun
Brinkop, Sabine
Ponater, Michael
Dietmüller, Simone
Jöckel, Patrick
Garny, Hella
Tsati, Eleni
Dahlmann, Katrin
Sovde, O.A.
Fuglestvedt, J.S.
Berntsen, T.
Shine, K.P.
Irvine, Emma A.
Champougny, T.
Hullah, P.
author_sort Grewe, Volker
title Aircraft routing with minimal climate impact: The REACT4C climate cost function modelling approach (V1.0)
title_short Aircraft routing with minimal climate impact: The REACT4C climate cost function modelling approach (V1.0)
title_full Aircraft routing with minimal climate impact: The REACT4C climate cost function modelling approach (V1.0)
title_fullStr Aircraft routing with minimal climate impact: The REACT4C climate cost function modelling approach (V1.0)
title_full_unstemmed Aircraft routing with minimal climate impact: The REACT4C climate cost function modelling approach (V1.0)
title_sort aircraft routing with minimal climate impact: the react4c climate cost function modelling approach (v1.0)
publisher Copernicus Publications
publishDate 2014
url https://elib.dlr.de/86884/
http://www.geosci-model-dev.net/7/175/2014/gmd-7-175-2014.pdf
genre North Atlantic
genre_facet North Atlantic
op_relation Grewe, Volker und Frömming, Christine und Matthes, Sigrun und Brinkop, Sabine und Ponater, Michael und Dietmüller, Simone und Jöckel, Patrick und Garny, Hella und Tsati, Eleni und Dahlmann, Katrin und Sovde, O.A. und Fuglestvedt, J.S. und Berntsen, T. und Shine, K.P. und Irvine, Emma A. und Champougny, T. und Hullah, P. (2014) Aircraft routing with minimal climate impact: The REACT4C climate cost function modelling approach (V1.0). Geoscientific Model Development, Seiten 175-201. Copernicus Publications. DOI:10.5194/gmd-7-175-2014 <https://doi.org/10.5194/gmd-7-175-2014> ISSN 1991-959X
op_doi https://doi.org/10.5194/gmd-7-175-2014
container_title Geoscientific Model Development
container_volume 7
container_issue 1
container_start_page 175
op_container_end_page 201
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