Chemical Observations of a Polar Vortex Intrusion
An intrusion of vortex edge air in D the interior of the Arctic polar vortex was observed on the January 31,2005 flight of the NASA DC-8 aircraft. This intrusion was identified as anomalously high values of ozone by the AROTAL and DIAL lidars. Our analysis shows that this intrusion formed when a blo...
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2006
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| Online Access: | http://hdl.handle.net/2060/20060013186 |
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ftnasantrs:oai:casi.ntrs.nasa.gov:20060013186 |
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ftnasantrs:oai:casi.ntrs.nasa.gov:20060013186 2023-05-15T15:06:59+02:00 Chemical Observations of a Polar Vortex Intrusion Douglass, A. R. Browell, E. Kawa, S. R. McGee, T. J. Read, W. Froidevaux, L. Waters, J. Schoeberl, M. R. Livesey, N. Unclassified, Unlimited, Publicly available [2006] application/pdf http://hdl.handle.net/2060/20060013186 unknown Document ID: 20060013186 http://hdl.handle.net/2060/20060013186 Copyright, Distribution as joint owner in the copyright CASI Meteorology and Climatology 2006 ftnasantrs 2018-06-09T23:00:41Z An intrusion of vortex edge air in D the interior of the Arctic polar vortex was observed on the January 31,2005 flight of the NASA DC-8 aircraft. This intrusion was identified as anomalously high values of ozone by the AROTAL and DIAL lidars. Our analysis shows that this intrusion formed when a blocking feature near Iceland collapsed, allowing edge air to sweep into the vortex interior. along the DC-8 flight track also shows the intrusion in both ozone and HNO3. Polar Stratospheric Clouds (PSCs) were observed by the DIAL lidar on the DC-8. The spatial variability of the PSCs can be explained using MLS HNO3 and H2O observations and meteorological analysis temperatures. We also estimate vortex denitrification using the relationship between N2O and HNO3. Reverse domain fill back trajectory calculations are used to focus on the features in the MLS data. The trajectory results improve the agreement between lidar measured ozone and MLS ozone and also improve the agreement between the HNO3 measurements PSC locations. The back trajectory calculations allow us to compute the local denitrification rate and reduction of HCl within the filament. We estimate a denitrification rate of about lO%/day after exposure to below PSC formation temperature. Analysis of Aura MLS observations made Other/Unknown Material Arctic Iceland NASA Technical Reports Server (NTRS) Arctic |
| institution |
Open Polar |
| collection |
NASA Technical Reports Server (NTRS) |
| op_collection_id |
ftnasantrs |
| language |
unknown |
| topic |
Meteorology and Climatology |
| spellingShingle |
Meteorology and Climatology Douglass, A. R. Browell, E. Kawa, S. R. McGee, T. J. Read, W. Froidevaux, L. Waters, J. Schoeberl, M. R. Livesey, N. Chemical Observations of a Polar Vortex Intrusion |
| topic_facet |
Meteorology and Climatology |
| description |
An intrusion of vortex edge air in D the interior of the Arctic polar vortex was observed on the January 31,2005 flight of the NASA DC-8 aircraft. This intrusion was identified as anomalously high values of ozone by the AROTAL and DIAL lidars. Our analysis shows that this intrusion formed when a blocking feature near Iceland collapsed, allowing edge air to sweep into the vortex interior. along the DC-8 flight track also shows the intrusion in both ozone and HNO3. Polar Stratospheric Clouds (PSCs) were observed by the DIAL lidar on the DC-8. The spatial variability of the PSCs can be explained using MLS HNO3 and H2O observations and meteorological analysis temperatures. We also estimate vortex denitrification using the relationship between N2O and HNO3. Reverse domain fill back trajectory calculations are used to focus on the features in the MLS data. The trajectory results improve the agreement between lidar measured ozone and MLS ozone and also improve the agreement between the HNO3 measurements PSC locations. The back trajectory calculations allow us to compute the local denitrification rate and reduction of HCl within the filament. We estimate a denitrification rate of about lO%/day after exposure to below PSC formation temperature. Analysis of Aura MLS observations made |
| author |
Douglass, A. R. Browell, E. Kawa, S. R. McGee, T. J. Read, W. Froidevaux, L. Waters, J. Schoeberl, M. R. Livesey, N. |
| author_facet |
Douglass, A. R. Browell, E. Kawa, S. R. McGee, T. J. Read, W. Froidevaux, L. Waters, J. Schoeberl, M. R. Livesey, N. |
| author_sort |
Douglass, A. R. |
| title |
Chemical Observations of a Polar Vortex Intrusion |
| title_short |
Chemical Observations of a Polar Vortex Intrusion |
| title_full |
Chemical Observations of a Polar Vortex Intrusion |
| title_fullStr |
Chemical Observations of a Polar Vortex Intrusion |
| title_full_unstemmed |
Chemical Observations of a Polar Vortex Intrusion |
| title_sort |
chemical observations of a polar vortex intrusion |
| publishDate |
2006 |
| url |
http://hdl.handle.net/2060/20060013186 |
| op_coverage |
Unclassified, Unlimited, Publicly available |
| geographic |
Arctic |
| geographic_facet |
Arctic |
| genre |
Arctic Iceland |
| genre_facet |
Arctic Iceland |
| op_source |
CASI |
| op_relation |
Document ID: 20060013186 http://hdl.handle.net/2060/20060013186 |
| op_rights |
Copyright, Distribution as joint owner in the copyright |
| _version_ |
1766338571551113216 |