Large-scale transport into the Arctic: the roles of the midlatitude jet and the Hadley Cell
<p>Transport from the Northern Hemisphere (NH) midlatitudes to the Arctic plays a crucial role in determining the abundance of trace gases and aerosols that are important to Arctic climate via impacts on radiation and chemistry. Here we examine this transport using an idealized tracer with a f...
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| Format: | Article |
| Language: | English |
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Copernicus Publications
2019-04-01
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| Series: | Atmospheric Chemistry and Physics |
| Online Access: | https://www.atmos-chem-phys.net/19/5511/2019/acp-19-5511-2019.pdf |
| id |
doaj-15e36c85b15e4b77bb43bb6c995751ce |
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| record_format |
Article |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
H. Yang D. W. Waugh D. W. Waugh C. Orbe G. Zeng O. Morgenstern D. E. Kinnison J.-F. Lamarque S. Tilmes D. A. Plummer P. Jöckel S. E. Strahan S. E. Strahan K. A. Stone K. A. Stone K. A. Stone R. Schofield R. Schofield |
| spellingShingle |
H. Yang D. W. Waugh D. W. Waugh C. Orbe G. Zeng O. Morgenstern D. E. Kinnison J.-F. Lamarque S. Tilmes D. A. Plummer P. Jöckel S. E. Strahan S. E. Strahan K. A. Stone K. A. Stone K. A. Stone R. Schofield R. Schofield Large-scale transport into the Arctic: the roles of the midlatitude jet and the Hadley Cell Atmospheric Chemistry and Physics |
| author_facet |
H. Yang D. W. Waugh D. W. Waugh C. Orbe G. Zeng O. Morgenstern D. E. Kinnison J.-F. Lamarque S. Tilmes D. A. Plummer P. Jöckel S. E. Strahan S. E. Strahan K. A. Stone K. A. Stone K. A. Stone R. Schofield R. Schofield |
| author_sort |
H. Yang |
| title |
Large-scale transport into the Arctic: the roles of the midlatitude jet and the Hadley Cell |
| title_short |
Large-scale transport into the Arctic: the roles of the midlatitude jet and the Hadley Cell |
| title_full |
Large-scale transport into the Arctic: the roles of the midlatitude jet and the Hadley Cell |
| title_fullStr |
Large-scale transport into the Arctic: the roles of the midlatitude jet and the Hadley Cell |
| title_full_unstemmed |
Large-scale transport into the Arctic: the roles of the midlatitude jet and the Hadley Cell |
| title_sort |
large-scale transport into the arctic: the roles of the midlatitude jet and the hadley cell |
| publisher |
Copernicus Publications |
| series |
Atmospheric Chemistry and Physics |
| issn |
1680-7316 1680-7324 |
| publishDate |
2019-04-01 |
| description |
<p>Transport from the Northern Hemisphere (NH) midlatitudes to the
Arctic plays a crucial role in determining the abundance of trace gases and
aerosols that are important to Arctic climate via impacts on radiation and
chemistry. Here we examine this transport using an idealized tracer with a
fixed lifetime and predominantly midlatitude land-based sources in models
participating in the Chemistry Climate Model Initiative (CCMI). We show that
there is a 25 %–45 % difference in the Arctic concentrations of this tracer
among the models. This spread is correlated with the spread in the location
of the Pacific jet, as well as the spread in the location of the Hadley Cell
(HC) edge, which varies consistently with jet latitude. Our results suggest
that it is likely that the HC-related zonal-mean meridional transport rather
than the jet-related eddy mixing is the major contributor to the inter-model
spread in the transport of land-based tracers into the Arctic. Specifically,
in models with a more northern jet, the HC generally extends further north
and the tracer source region is mostly covered by surface southward flow
associated with the lower branch of the HC, resulting in less efficient
transport poleward to the Arctic. During boreal summer, there are poleward
biases in jet location in free-running models, and these models likely
underestimate the rate of transport into the Arctic. Models using specified
dynamics do not have biases in the jet location, but do have biases in the
surface meridional flow, which may result in differences in transport into
the Arctic. In addition to the land-based tracer, the midlatitude-to-Arctic
transport is further examined by another idealized tracer with zonally
uniform sources. With equal sources from both land and ocean, the inter-model
spread of this zonally uniform tracer is more related to variations in
parameterized convection over oceans rather than variations in HC extent,
particularly during boreal winter. This suggests that transport of land-based
and oceanic<span id="page5512"/> tracers or aerosols towards the Arctic differs in pathways and
therefore their corresponding inter-model variabilities result from different
physical processes.</p> |
| url |
https://www.atmos-chem-phys.net/19/5511/2019/acp-19-5511-2019.pdf |
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doaj-15e36c85b15e4b77bb43bb6c995751ce2020-11-25T00:29:05ZengCopernicus PublicationsAtmospheric Chemistry and Physics1680-73161680-73242019-04-01195511552810.5194/acp-19-5511-2019Large-scale transport into the Arctic: the roles of the midlatitude jet and the Hadley CellH. Yang0D. W. Waugh1D. W. Waugh2C. Orbe3G. Zeng4O. Morgenstern5D. E. Kinnison6J.-F. Lamarque7S. Tilmes8D. A. Plummer9P. Jöckel10S. E. Strahan11S. E. Strahan12K. A. Stone13K. A. Stone14K. A. Stone15R. Schofield16R. Schofield17Department of Earth and Planetary Sciences, Johns Hopkins University, Baltimore, Maryland, USADepartment of Earth and Planetary Sciences, Johns Hopkins University, Baltimore, Maryland, USASchool of Mathematics, University of New South Wales, Sydney, AustraliaNASA Goddard Institute for Space Studies, New York, New York, USANational Institute of Water and Atmospheric Research, Wellington, New ZealandNational Institute of Water and Atmospheric Research, Wellington, New ZealandNational Center for Atmospheric Research (NCAR), Atmospheric Chemistry Observations and Modeling (ACOM) Laboratory, Boulder, Colorado, USANational Center for Atmospheric Research (NCAR), Atmospheric Chemistry Observations and Modeling (ACOM) Laboratory, Boulder, Colorado, USANational Center for Atmospheric Research (NCAR), Atmospheric Chemistry Observations and Modeling (ACOM) Laboratory, Boulder, Colorado, USAClimate Research Branch, Environment and Climate Change Canada, Montreal, QC, CanadaDeutsches Zentrum für Luft- und Raumfahrt (DLR), Institut für Physik der Atmosphäre, Oberpfaffenhofen, GermanyAtmospheric Chemistry and Dynamics Laboratory, NASA Goddard Space Flight Center, Greenbelt, Maryland, USAUniversities Space Research Association, Columbia, Maryland, USASchool of Earth Sciences, University of Melbourne, Melbourne, Victoria 3010, AustraliaARC Centre of Excellence for Climate System Science, University of New South Wales, Sydney, New South Wales 2052, Australianow at: Department of Earth, Atmospheric and Planetary Sciences, Massachusetts Institute of Technology, Cambridge, Massachusetts 02139-4307, USASchool of Earth Sciences, University of Melbourne, Melbourne, Victoria 3010, AustraliaARC Centre of Excellence for Climate System Science, University of New South Wales, Sydney, New South Wales 2052, Australia<p>Transport from the Northern Hemisphere (NH) midlatitudes to the Arctic plays a crucial role in determining the abundance of trace gases and aerosols that are important to Arctic climate via impacts on radiation and chemistry. Here we examine this transport using an idealized tracer with a fixed lifetime and predominantly midlatitude land-based sources in models participating in the Chemistry Climate Model Initiative (CCMI). We show that there is a 25 %–45 % difference in the Arctic concentrations of this tracer among the models. This spread is correlated with the spread in the location of the Pacific jet, as well as the spread in the location of the Hadley Cell (HC) edge, which varies consistently with jet latitude. Our results suggest that it is likely that the HC-related zonal-mean meridional transport rather than the jet-related eddy mixing is the major contributor to the inter-model spread in the transport of land-based tracers into the Arctic. Specifically, in models with a more northern jet, the HC generally extends further north and the tracer source region is mostly covered by surface southward flow associated with the lower branch of the HC, resulting in less efficient transport poleward to the Arctic. During boreal summer, there are poleward biases in jet location in free-running models, and these models likely underestimate the rate of transport into the Arctic. Models using specified dynamics do not have biases in the jet location, but do have biases in the surface meridional flow, which may result in differences in transport into the Arctic. In addition to the land-based tracer, the midlatitude-to-Arctic transport is further examined by another idealized tracer with zonally uniform sources. With equal sources from both land and ocean, the inter-model spread of this zonally uniform tracer is more related to variations in parameterized convection over oceans rather than variations in HC extent, particularly during boreal winter. This suggests that transport of land-based and oceanic<span id="page5512"/> tracers or aerosols towards the Arctic differs in pathways and therefore their corresponding inter-model variabilities result from different physical processes.</p>https://www.atmos-chem-phys.net/19/5511/2019/acp-19-5511-2019.pdf |