TransCom N 2 O model inter-comparison – Part 1: Assessing the influence of transport and surface fluxes on tropospheric N 2 O variability

We present a comparison of chemistry-transport models (TransCom-N2O) to examine the importance of atmospheric transport and surface fluxes on the variability of N2O mixing ratios in the troposphere. Six different models and two model variants participated in the inter-comparison and simulations were...

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Published in:Atmospheric Chemistry and Physics
Main Authors: THOMPSON, R., PATRA, P., ISHIJIMA, K., SAIKAWA, E., CORAZZA, M., KARSTENS, U., WILSON, C., BERGAMASCHI, P., DLUGOKENCKY, E., SWEENEY, C., PRINN, R., WEISS, R., O'DOHERTY, S., FRASER, P., STEELE, L., KRUMMEL, P., SAUNOIS, M., CHIPPERFIELD, M., BOUSQUET, P.
Format: Other/Unknown Material
Language:English
Published: European Geosciences Union 2014
Subjects:
Planète et Univers [physics]/Océan
Atmosphère
Grim
South Pole
Southern Ocean
South pole
Online Access:https://oskar-bordeaux.fr/handle/20.500.12278/35450
https://doi.org/10.5194/acp-14-4349-2014
id ftoskarbordeaux:oai:oskar-bordeaux.fr:20.500.12278/35450
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spelling ftoskarbordeaux:oai:oskar-bordeaux.fr:20.500.12278/35450 2023-05-15T18:23:24+02:00 TransCom N 2 O model inter-comparison – Part 1: Assessing the influence of transport and surface fluxes on tropospheric N 2 O variability THOMPSON, R. PATRA, P. ISHIJIMA, K. SAIKAWA, E. CORAZZA, M. KARSTENS, U. WILSON, C. BERGAMASCHI, P. DLUGOKENCKY, E. SWEENEY, C. PRINN, R. WEISS, R. O'DOHERTY, S. FRASER, P. STEELE, L. KRUMMEL, P. SAUNOIS, M. CHIPPERFIELD, M. BOUSQUET, P. 2014 https://oskar-bordeaux.fr/handle/20.500.12278/35450 https://doi.org/10.5194/acp-14-4349-2014 en eng European Geosciences Union 1680-7316 https://oskar-bordeaux.fr/handle/20.500.12278/35450 doi:10.5194/acp-14-4349-2014 Planète et Univers [physics]/Océan Atmosphère Article de revue 2014 ftoskarbordeaux https://doi.org/10.5194/acp-14-4349-2014 2021-05-11T22:30:26Z We present a comparison of chemistry-transport models (TransCom-N2O) to examine the importance of atmospheric transport and surface fluxes on the variability of N2O mixing ratios in the troposphere. Six different models and two model variants participated in the inter-comparison and simulations were made for the period 2006 to 2009. In addition to N2O, simulations of CFC-12 and SF6 were made by a subset of four of the models to provide information on the models' proficiency in stratosphere–troposphere exchange (STE) and meridional transport, respectively. The same prior emissions were used by all models to restrict differences among models to transport and chemistry alone. Four different N2O flux scenarios totalling between 14 and 17 TgN yr−1 (for 2005) globally were also compared. The modelled N2O mixing ratios were assessed against observations from in situ stations, discrete air sampling networks and aircraft. All models adequately captured the large-scale patterns of N2O and the vertical gradient from the troposphere to the stratosphere and most models also adequately captured the N2O tropospheric growth rate. However, all models underestimated the inter-hemispheric N2O gradient by at least 0.33 parts per billion (ppb), equivalent to 1.5 TgN, which, even after accounting for an overestimate of emissions in the Southern Ocean of circa 1.0 TgN, points to a likely underestimate of the Northern Hemisphere source by up to 0.5 TgN and/or an overestimate of STE in the Northern Hemisphere. Comparison with aircraft data reveal that the models overestimate the amplitude of the N2O seasonal cycle at Hawaii (21° N, 158° W) below circa 6000 m, suggesting an overestimate of the importance of stratosphere to troposphere transport in the lower troposphere at this latitude. In the Northern Hemisphere, most of the models that provided CFC-12 simulations captured the phase of the CFC-12, seasonal cycle, indicating a reasonable representation of the timing of STE. However, for N2O all models simulated a too early minimum by 2 to 3 months owing to errors in the seasonal cycle in the prior soil emissions, which was not adequately represented by the terrestrial biosphere model. In the Southern Hemisphere, most models failed to capture the N2O and CFC-12 seasonality at Cape Grim, Tasmania, and all failed at the South Pole, whereas for SF6, all models could capture the seasonality at all sites, suggesting that there are large errors in modelled vertical transport in high southern latitudes. Other/Unknown Material South pole Southern Ocean OSKAR Bordeaux (Open Science Knowledge ARchive) Grim ENVELOPE(-64.486,-64.486,-65.379,-65.379) South Pole Southern Ocean Atmospheric Chemistry and Physics 14 8 4349 4368
institution Open Polar
collection OSKAR Bordeaux (Open Science Knowledge ARchive)
op_collection_id ftoskarbordeaux
language English
topic Planète et Univers [physics]/Océan
Atmosphère
spellingShingle Planète et Univers [physics]/Océan
Atmosphère
THOMPSON, R.
PATRA, P.
ISHIJIMA, K.
SAIKAWA, E.
CORAZZA, M.
KARSTENS, U.
WILSON, C.
BERGAMASCHI, P.
DLUGOKENCKY, E.
SWEENEY, C.
PRINN, R.
WEISS, R.
O'DOHERTY, S.
FRASER, P.
STEELE, L.
KRUMMEL, P.
SAUNOIS, M.
CHIPPERFIELD, M.
BOUSQUET, P.
TransCom N 2 O model inter-comparison – Part 1: Assessing the influence of transport and surface fluxes on tropospheric N 2 O variability
topic_facet Planète et Univers [physics]/Océan
Atmosphère
description We present a comparison of chemistry-transport models (TransCom-N2O) to examine the importance of atmospheric transport and surface fluxes on the variability of N2O mixing ratios in the troposphere. Six different models and two model variants participated in the inter-comparison and simulations were made for the period 2006 to 2009. In addition to N2O, simulations of CFC-12 and SF6 were made by a subset of four of the models to provide information on the models' proficiency in stratosphere–troposphere exchange (STE) and meridional transport, respectively. The same prior emissions were used by all models to restrict differences among models to transport and chemistry alone. Four different N2O flux scenarios totalling between 14 and 17 TgN yr−1 (for 2005) globally were also compared. The modelled N2O mixing ratios were assessed against observations from in situ stations, discrete air sampling networks and aircraft. All models adequately captured the large-scale patterns of N2O and the vertical gradient from the troposphere to the stratosphere and most models also adequately captured the N2O tropospheric growth rate. However, all models underestimated the inter-hemispheric N2O gradient by at least 0.33 parts per billion (ppb), equivalent to 1.5 TgN, which, even after accounting for an overestimate of emissions in the Southern Ocean of circa 1.0 TgN, points to a likely underestimate of the Northern Hemisphere source by up to 0.5 TgN and/or an overestimate of STE in the Northern Hemisphere. Comparison with aircraft data reveal that the models overestimate the amplitude of the N2O seasonal cycle at Hawaii (21° N, 158° W) below circa 6000 m, suggesting an overestimate of the importance of stratosphere to troposphere transport in the lower troposphere at this latitude. In the Northern Hemisphere, most of the models that provided CFC-12 simulations captured the phase of the CFC-12, seasonal cycle, indicating a reasonable representation of the timing of STE. However, for N2O all models simulated a too early minimum by 2 to 3 months owing to errors in the seasonal cycle in the prior soil emissions, which was not adequately represented by the terrestrial biosphere model. In the Southern Hemisphere, most models failed to capture the N2O and CFC-12 seasonality at Cape Grim, Tasmania, and all failed at the South Pole, whereas for SF6, all models could capture the seasonality at all sites, suggesting that there are large errors in modelled vertical transport in high southern latitudes.
format Other/Unknown Material
author THOMPSON, R.
PATRA, P.
ISHIJIMA, K.
SAIKAWA, E.
CORAZZA, M.
KARSTENS, U.
WILSON, C.
BERGAMASCHI, P.
DLUGOKENCKY, E.
SWEENEY, C.
PRINN, R.
WEISS, R.
O'DOHERTY, S.
FRASER, P.
STEELE, L.
KRUMMEL, P.
SAUNOIS, M.
CHIPPERFIELD, M.
BOUSQUET, P.
author_facet THOMPSON, R.
PATRA, P.
ISHIJIMA, K.
SAIKAWA, E.
CORAZZA, M.
KARSTENS, U.
WILSON, C.
BERGAMASCHI, P.
DLUGOKENCKY, E.
SWEENEY, C.
PRINN, R.
WEISS, R.
O'DOHERTY, S.
FRASER, P.
STEELE, L.
KRUMMEL, P.
SAUNOIS, M.
CHIPPERFIELD, M.
BOUSQUET, P.
author_sort THOMPSON, R.
title TransCom N 2 O model inter-comparison – Part 1: Assessing the influence of transport and surface fluxes on tropospheric N 2 O variability
title_short TransCom N 2 O model inter-comparison – Part 1: Assessing the influence of transport and surface fluxes on tropospheric N 2 O variability
title_full TransCom N 2 O model inter-comparison – Part 1: Assessing the influence of transport and surface fluxes on tropospheric N 2 O variability
title_fullStr TransCom N 2 O model inter-comparison – Part 1: Assessing the influence of transport and surface fluxes on tropospheric N 2 O variability
title_full_unstemmed TransCom N 2 O model inter-comparison – Part 1: Assessing the influence of transport and surface fluxes on tropospheric N 2 O variability
title_sort transcom n 2 o model inter-comparison – part 1: assessing the influence of transport and surface fluxes on tropospheric n 2 o variability
publisher European Geosciences Union
publishDate 2014
url https://oskar-bordeaux.fr/handle/20.500.12278/35450
https://doi.org/10.5194/acp-14-4349-2014
long_lat ENVELOPE(-64.486,-64.486,-65.379,-65.379)
geographic Grim
South Pole
Southern Ocean
geographic_facet Grim
South Pole
Southern Ocean
genre South pole
Southern Ocean
genre_facet South pole
Southern Ocean
op_relation 1680-7316
https://oskar-bordeaux.fr/handle/20.500.12278/35450
doi:10.5194/acp-14-4349-2014
op_doi https://doi.org/10.5194/acp-14-4349-2014
container_title Atmospheric Chemistry and Physics
container_volume 14
container_issue 8
container_start_page 4349
op_container_end_page 4368
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