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Impact of perturbations to nitrogen oxide emissions from global aviation.

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Impact of perturbations to nitrogen oxide emissions from global aviation. / Köhler, Marcus O.; Rädel, Gaby; Dessens, Olivier et al.
In: Journal of Geophysical Research: Atmospheres, Vol. 113, 10.06.2008, p. D11305.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Köhler, MO, Rädel, G, Dessens, O, Shine, KP, Rogers, HL, Wild, O & Pyle, JA 2008, 'Impact of perturbations to nitrogen oxide emissions from global aviation.', Journal of Geophysical Research: Atmospheres, vol. 113, pp. D11305. https://doi.org/10.1029/2007JD009140

APA

Köhler, M. O., Rädel, G., Dessens, O., Shine, K. P., Rogers, H. L., Wild, O., & Pyle, J. A. (2008). Impact of perturbations to nitrogen oxide emissions from global aviation. Journal of Geophysical Research: Atmospheres, 113, D11305. https://doi.org/10.1029/2007JD009140

Vancouver

Köhler MO, Rädel G, Dessens O, Shine KP, Rogers HL, Wild O et al. Impact of perturbations to nitrogen oxide emissions from global aviation. Journal of Geophysical Research: Atmospheres. 2008 Jun 10;113:D11305. doi: 10.1029/2007JD009140

Author

Köhler, Marcus O. ; Rädel, Gaby ; Dessens, Olivier et al. / Impact of perturbations to nitrogen oxide emissions from global aviation. In: Journal of Geophysical Research: Atmospheres. 2008 ; Vol. 113. pp. D11305.

Bibtex

@article{559daae4ad234572a0b494e47a249621,
title = "Impact of perturbations to nitrogen oxide emissions from global aviation.",
abstract = "The atmospheric response to perturbations in NO x emissions from global air traffic is investigated by performing a coherent set of sensitivity experiments. The importance of cruise altitude, size of the emission perturbation and geographical distribution of emissions is systematically analyzed using two global chemistry transport models and an off-line radiative transfer model. NO x emissions from a contemporary aircraft inventory have been used to assess the impact of global air traffic on ozone and methane. In further experiments the NO x emissions are perturbed, in turn, in 16 cruise altitude bands between 5 and 15 km altitude. In the p-TOMCAT model we diagnose an annual mean ozone increase of up to 6 ppbv and a decrease in the methane lifetime of 3% due to global air traffic in 2002. Associated radiative forcings of 30 mWm−2 for ozone and −19 mWm−2 for methane are diagnosed; a simple method is used to estimate the forcing due to the methane-induced ozone change and this yields an additional −11 mWm−2. Results show that up to the tropopause, ozone production efficiency and resulting impacts increase per emitted mass of NO x with the altitude of the perturbation. Between 11 and 15 km we find that the geographical location of the NO x emissions plays a crucial role in the potential O3 impact and lifetime change of CH4. We show that changes in flight routing in this altitude range can have significant consequences for O3 and CH4 concentrations. Overall, we demonstrate a linear relationship in the atmospheric response to small emission changes which can be used to predict the importance of perturbations about the reference aircraft emissions profile, provided the geographical distribution of the emissions is not altered significantly.",
keywords = "Aviation, climate, ozone, methane, tropospheric chemistry",
author = "K{\"o}hler, {Marcus O.} and Gaby R{\"a}del and Olivier Dessens and Shine, {Keith P.} and Rogers, {Helen L.} and Oliver Wild and Pyle, {John A.}",
note = "Copyright (2008) American Geophysical Union. Further reproduction or electronic distribution is not permitted",
year = "2008",
month = jun,
day = "10",
doi = "10.1029/2007JD009140",
language = "English",
volume = "113",
pages = "D11305",
journal = "Journal of Geophysical Research: Atmospheres",
issn = "0747-7309",
publisher = "Wiley-Blackwell Publishing Ltd",

}

RIS

TY - JOUR

T1 - Impact of perturbations to nitrogen oxide emissions from global aviation.

AU - Köhler, Marcus O.

AU - Rädel, Gaby

AU - Dessens, Olivier

AU - Shine, Keith P.

AU - Rogers, Helen L.

AU - Wild, Oliver

AU - Pyle, John A.

N1 - Copyright (2008) American Geophysical Union. Further reproduction or electronic distribution is not permitted

PY - 2008/6/10

Y1 - 2008/6/10

N2 - The atmospheric response to perturbations in NO x emissions from global air traffic is investigated by performing a coherent set of sensitivity experiments. The importance of cruise altitude, size of the emission perturbation and geographical distribution of emissions is systematically analyzed using two global chemistry transport models and an off-line radiative transfer model. NO x emissions from a contemporary aircraft inventory have been used to assess the impact of global air traffic on ozone and methane. In further experiments the NO x emissions are perturbed, in turn, in 16 cruise altitude bands between 5 and 15 km altitude. In the p-TOMCAT model we diagnose an annual mean ozone increase of up to 6 ppbv and a decrease in the methane lifetime of 3% due to global air traffic in 2002. Associated radiative forcings of 30 mWm−2 for ozone and −19 mWm−2 for methane are diagnosed; a simple method is used to estimate the forcing due to the methane-induced ozone change and this yields an additional −11 mWm−2. Results show that up to the tropopause, ozone production efficiency and resulting impacts increase per emitted mass of NO x with the altitude of the perturbation. Between 11 and 15 km we find that the geographical location of the NO x emissions plays a crucial role in the potential O3 impact and lifetime change of CH4. We show that changes in flight routing in this altitude range can have significant consequences for O3 and CH4 concentrations. Overall, we demonstrate a linear relationship in the atmospheric response to small emission changes which can be used to predict the importance of perturbations about the reference aircraft emissions profile, provided the geographical distribution of the emissions is not altered significantly.

AB - The atmospheric response to perturbations in NO x emissions from global air traffic is investigated by performing a coherent set of sensitivity experiments. The importance of cruise altitude, size of the emission perturbation and geographical distribution of emissions is systematically analyzed using two global chemistry transport models and an off-line radiative transfer model. NO x emissions from a contemporary aircraft inventory have been used to assess the impact of global air traffic on ozone and methane. In further experiments the NO x emissions are perturbed, in turn, in 16 cruise altitude bands between 5 and 15 km altitude. In the p-TOMCAT model we diagnose an annual mean ozone increase of up to 6 ppbv and a decrease in the methane lifetime of 3% due to global air traffic in 2002. Associated radiative forcings of 30 mWm−2 for ozone and −19 mWm−2 for methane are diagnosed; a simple method is used to estimate the forcing due to the methane-induced ozone change and this yields an additional −11 mWm−2. Results show that up to the tropopause, ozone production efficiency and resulting impacts increase per emitted mass of NO x with the altitude of the perturbation. Between 11 and 15 km we find that the geographical location of the NO x emissions plays a crucial role in the potential O3 impact and lifetime change of CH4. We show that changes in flight routing in this altitude range can have significant consequences for O3 and CH4 concentrations. Overall, we demonstrate a linear relationship in the atmospheric response to small emission changes which can be used to predict the importance of perturbations about the reference aircraft emissions profile, provided the geographical distribution of the emissions is not altered significantly.

KW - Aviation

KW - climate

KW - ozone

KW - methane

KW - tropospheric chemistry

U2 - 10.1029/2007JD009140

DO - 10.1029/2007JD009140

M3 - Journal article

VL - 113

SP - D11305

JO - Journal of Geophysical Research: Atmospheres

JF - Journal of Geophysical Research: Atmospheres

SN - 0747-7309

ER -