Understanding the changes of stratospheric water vapor in coupled chemistry-climate model simulations
Past and future climate simulations from the Goddard Earth Observing System Chemistry–Climate Model (GEOS CCM), with specified boundary conditions for sea surface temperature, sea ice, and trace gas emissions, have been analyzed to assess trends and possible causes of changes in stratospheric water...
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2008
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| Online Access: | http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.610.5895 http://www.jhu.edu/~dwaugh1/papers/Oman_etal_JAS2008.pdf |
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ftciteseerx:oai:CiteSeerX.psu:10.1.1.610.5895 2023-05-15T18:18:37+02:00 Understanding the changes of stratospheric water vapor in coupled chemistry-climate model simulations Luke Oman Darryn W. Waugh Steven Pawson Richard S. Stolarski J. Eric Nielsen The Pennsylvania State University CiteSeerX Archives 2008 application/pdf http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.610.5895 http://www.jhu.edu/~dwaugh1/papers/Oman_etal_JAS2008.pdf en eng http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.610.5895 http://www.jhu.edu/~dwaugh1/papers/Oman_etal_JAS2008.pdf Metadata may be used without restrictions as long as the oai identifier remains attached to it. http://www.jhu.edu/~dwaugh1/papers/Oman_etal_JAS2008.pdf text 2008 ftciteseerx 2016-01-08T14:29:27Z Past and future climate simulations from the Goddard Earth Observing System Chemistry–Climate Model (GEOS CCM), with specified boundary conditions for sea surface temperature, sea ice, and trace gas emissions, have been analyzed to assess trends and possible causes of changes in stratospheric water vapor. The simulated distribution of stratospheric water vapor in the 1990s compares well with observations. Changes in the cold point temperatures near the tropical tropopause can explain differences in entry stratospheric water vapor. The average saturation mixing ratio of a 20 ° latitude by 15 ° longitude region surrounding the minimum tropical saturation mixing ratio is shown to be a useful diagnostic for entry stratospheric water vapor and does an excellent job reconstructing the annual average entry stratospheric water vapor over the period 1950–2100. The simulated stratospheric water vapor increases over the 50 yr between 1950 and 2000, primarily because of changes in methane concentrations, offset by a slight decrease in tropical cold point temperatures. Stratospheric water vapor is predicted to continue to increase over the twenty-first century, with increasing methane concentrations causing the majority of the trend to midcen-tury. Small increases in cold point temperature cause increases in the entry water vapor throughout the twenty-first century. The increasing trend in future water vapor is tempered by a decreasing contribution of methane oxidation owing to cooling stratospheric temperatures and by increased tropical upwelling, leading to a near-zero trend for the last 30 yr of the twenty-first century. 1. Text Sea ice Unknown Cold Point ENVELOPE(-58.833,-58.833,-62.167,-62.167) |
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Open Polar |
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ftciteseerx |
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English |
| description |
Past and future climate simulations from the Goddard Earth Observing System Chemistry–Climate Model (GEOS CCM), with specified boundary conditions for sea surface temperature, sea ice, and trace gas emissions, have been analyzed to assess trends and possible causes of changes in stratospheric water vapor. The simulated distribution of stratospheric water vapor in the 1990s compares well with observations. Changes in the cold point temperatures near the tropical tropopause can explain differences in entry stratospheric water vapor. The average saturation mixing ratio of a 20 ° latitude by 15 ° longitude region surrounding the minimum tropical saturation mixing ratio is shown to be a useful diagnostic for entry stratospheric water vapor and does an excellent job reconstructing the annual average entry stratospheric water vapor over the period 1950–2100. The simulated stratospheric water vapor increases over the 50 yr between 1950 and 2000, primarily because of changes in methane concentrations, offset by a slight decrease in tropical cold point temperatures. Stratospheric water vapor is predicted to continue to increase over the twenty-first century, with increasing methane concentrations causing the majority of the trend to midcen-tury. Small increases in cold point temperature cause increases in the entry water vapor throughout the twenty-first century. The increasing trend in future water vapor is tempered by a decreasing contribution of methane oxidation owing to cooling stratospheric temperatures and by increased tropical upwelling, leading to a near-zero trend for the last 30 yr of the twenty-first century. 1. |
| author2 |
The Pennsylvania State University CiteSeerX Archives |
| format |
Text |
| author |
Luke Oman Darryn W. Waugh Steven Pawson Richard S. Stolarski J. Eric Nielsen |
| spellingShingle |
Luke Oman Darryn W. Waugh Steven Pawson Richard S. Stolarski J. Eric Nielsen Understanding the changes of stratospheric water vapor in coupled chemistry-climate model simulations |
| author_facet |
Luke Oman Darryn W. Waugh Steven Pawson Richard S. Stolarski J. Eric Nielsen |
| author_sort |
Luke Oman |
| title |
Understanding the changes of stratospheric water vapor in coupled chemistry-climate model simulations |
| title_short |
Understanding the changes of stratospheric water vapor in coupled chemistry-climate model simulations |
| title_full |
Understanding the changes of stratospheric water vapor in coupled chemistry-climate model simulations |
| title_fullStr |
Understanding the changes of stratospheric water vapor in coupled chemistry-climate model simulations |
| title_full_unstemmed |
Understanding the changes of stratospheric water vapor in coupled chemistry-climate model simulations |
| title_sort |
understanding the changes of stratospheric water vapor in coupled chemistry-climate model simulations |
| publishDate |
2008 |
| url |
http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.610.5895 http://www.jhu.edu/~dwaugh1/papers/Oman_etal_JAS2008.pdf |
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ENVELOPE(-58.833,-58.833,-62.167,-62.167) |
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Cold Point |
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Cold Point |
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Sea ice |
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Sea ice |
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http://www.jhu.edu/~dwaugh1/papers/Oman_etal_JAS2008.pdf |
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http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.610.5895 http://www.jhu.edu/~dwaugh1/papers/Oman_etal_JAS2008.pdf |
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Metadata may be used without restrictions as long as the oai identifier remains attached to it. |
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1766195258512637952 |