Temporally and zonally varying atmospheric waveguides – climatologies and connections to quasi-stationary waves
<p>Atmospheric waveguides have been linked to amplified quasi-stationary Rossby waves and thus to extreme weather events in the mid-latitudes. Here, we compare different methods of calculating temporally and spatially varying waveguides, including different ways of separating the waveguides (b...
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Copernicus Publications
2025-05-01
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| Series: | Weather and Climate Dynamics |
| Online Access: | https://wcd.copernicus.org/articles/6/549/2025/wcd-6-549-2025.pdf |
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| author | R. H. White L. Mareshet Admasu |
| author_facet | R. H. White L. Mareshet Admasu |
| author_sort | R. H. White |
| collection | DOAJ |
| description | <p>Atmospheric waveguides have been linked to amplified quasi-stationary Rossby waves and thus to extreme weather events in the mid-latitudes. Here, we compare different methods of calculating temporally and spatially varying waveguides, including different ways of separating the waveguides (background flow) from waves. We compare waveguides from potential vorticity (PV) gradients (“PV waveguides”) with barotropic waveguides based on what is known as the stationary wavenumber, or <span class="inline-formula"><i>K</i><sub>S</sub></span> (“KS waveguides”), which is calculated from the zonal wind. The PV waveguides use a PV rolling-zonalization method to calculate the background flow. Conversely, the background flow for the KS waveguides is calculated using time and zonal filtering. We isolate the impacts of the background flow methodology from the different waveguide definitions by calculating PV waveguides using the same background flow calculation method as the KS waveguides. There are notable differences between the waveguides identified by the two definitions. KS waveguides are more frequent in summer than in winter, whilst PV waveguides are more frequent in winter, regardless of the method of background flow calculation. Composites of days with high spatially averaged waveguide strength over particular regions show distinct differences between the two waveguide definitions. Strong KS waveguides in some regions are associated with a double-jet structure, consistent with previous research; this structure is rarely present for strong PV waveguides. The presence of high geopotential heights occurs with the double-jet anomaly, consistent with atmospheric blocking creating the KS waveguide conditions through the influence on local zonal winds, highlighting that this methodology does not sufficiently separate non-linear perturbations (i.e. blocking) from the background flow (i.e. waveguides). Significant positive correlations exist between local waveguide strength and the amplitude of quasi-stationary waves; these correlations are stronger and more widespread for PV waveguides than for KS waveguides, and they are strongest when the rolling-zonalization background flow method is used. This study further cautions against using KS waveguides on temporally and/or zonally varying scales, and we recommend rolling-zonalization PV waveguides for the study of waveguides and their connections to quasi-stationary atmospheric waves.</p> |
| format | Article |
| id | doaj-art-495c9a2cd797407e9186e132fbc1f197 |
| institution | DOAJ |
| issn | 2698-4016 |
| language | English |
| publishDate | 2025-05-01 |
| publisher | Copernicus Publications |
| record_format | Article |
| series | Weather and Climate Dynamics |
| spelling | doaj-art-495c9a2cd797407e9186e132fbc1f1972025-08-20T03:09:44ZengCopernicus PublicationsWeather and Climate Dynamics2698-40162025-05-01654957010.5194/wcd-6-549-2025Temporally and zonally varying atmospheric waveguides – climatologies and connections to quasi-stationary wavesR. H. White0L. Mareshet Admasu1Department of Earth, Ocean and Atmospheric Sciences, University of British Columbia, Vancouver, BC, CanadaDepartment of Earth, Ocean and Atmospheric Sciences, University of British Columbia, Vancouver, BC, Canada<p>Atmospheric waveguides have been linked to amplified quasi-stationary Rossby waves and thus to extreme weather events in the mid-latitudes. Here, we compare different methods of calculating temporally and spatially varying waveguides, including different ways of separating the waveguides (background flow) from waves. We compare waveguides from potential vorticity (PV) gradients (“PV waveguides”) with barotropic waveguides based on what is known as the stationary wavenumber, or <span class="inline-formula"><i>K</i><sub>S</sub></span> (“KS waveguides”), which is calculated from the zonal wind. The PV waveguides use a PV rolling-zonalization method to calculate the background flow. Conversely, the background flow for the KS waveguides is calculated using time and zonal filtering. We isolate the impacts of the background flow methodology from the different waveguide definitions by calculating PV waveguides using the same background flow calculation method as the KS waveguides. There are notable differences between the waveguides identified by the two definitions. KS waveguides are more frequent in summer than in winter, whilst PV waveguides are more frequent in winter, regardless of the method of background flow calculation. Composites of days with high spatially averaged waveguide strength over particular regions show distinct differences between the two waveguide definitions. Strong KS waveguides in some regions are associated with a double-jet structure, consistent with previous research; this structure is rarely present for strong PV waveguides. The presence of high geopotential heights occurs with the double-jet anomaly, consistent with atmospheric blocking creating the KS waveguide conditions through the influence on local zonal winds, highlighting that this methodology does not sufficiently separate non-linear perturbations (i.e. blocking) from the background flow (i.e. waveguides). Significant positive correlations exist between local waveguide strength and the amplitude of quasi-stationary waves; these correlations are stronger and more widespread for PV waveguides than for KS waveguides, and they are strongest when the rolling-zonalization background flow method is used. This study further cautions against using KS waveguides on temporally and/or zonally varying scales, and we recommend rolling-zonalization PV waveguides for the study of waveguides and their connections to quasi-stationary atmospheric waves.</p>https://wcd.copernicus.org/articles/6/549/2025/wcd-6-549-2025.pdf |
| spellingShingle | R. H. White L. Mareshet Admasu Temporally and zonally varying atmospheric waveguides – climatologies and connections to quasi-stationary waves Weather and Climate Dynamics |
| title | Temporally and zonally varying atmospheric waveguides – climatologies and connections to quasi-stationary waves |
| title_full | Temporally and zonally varying atmospheric waveguides – climatologies and connections to quasi-stationary waves |
| title_fullStr | Temporally and zonally varying atmospheric waveguides – climatologies and connections to quasi-stationary waves |
| title_full_unstemmed | Temporally and zonally varying atmospheric waveguides – climatologies and connections to quasi-stationary waves |
| title_short | Temporally and zonally varying atmospheric waveguides – climatologies and connections to quasi-stationary waves |
| title_sort | temporally and zonally varying atmospheric waveguides climatologies and connections to quasi stationary waves |
| url | https://wcd.copernicus.org/articles/6/549/2025/wcd-6-549-2025.pdf |
| work_keys_str_mv | AT rhwhite temporallyandzonallyvaryingatmosphericwaveguidesclimatologiesandconnectionstoquasistationarywaves AT lmareshetadmasu temporallyandzonallyvaryingatmosphericwaveguidesclimatologiesandconnectionstoquasistationarywaves |