Potential vorticity structure of embedded convection in a warm conveyor belt and its relevance for large-scale dynamics
Warm conveyor belts (WCBs) are important airstreams in extratropical cyclones. They can influence large-scale flow evolution by modifying the potential vorticity (PV) distribution during their cross-isentropic ascent. Although WCBs are typically described as slantwise-ascending and stratiform-cloud-...
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Format: | Article in Journal/Newspaper |
Language: | English |
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Copernicus
2020
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Online Access: | https://hdl.handle.net/20.500.11850/456726 https://doi.org/10.3929/ethz-b-000456726 |
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ETH Zürich Research Collection |
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English |
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Warm conveyor belts (WCBs) are important airstreams in extratropical cyclones. They can influence large-scale flow evolution by modifying the potential vorticity (PV) distribution during their cross-isentropic ascent. Although WCBs are typically described as slantwise-ascending and stratiform-cloud-producing airstreams, recent studies identified convective activity embedded within the large-scale WCB cloud band. However, the impacts of this WCB-embedded convection have not been investigated in detail. In this study, we systematically analyze the influence of embedded convection in an eastern North Atlantic WCB on the cloud and precipitation structure, on the PV distribution, and on larger-scale flow. For this reason, we apply online trajectories in a high-resolution convection-permitting simulation and perform a composite analysis to compare quasi-vertically ascending convective WCB trajectories with typical slantwise-ascending WCB trajectories. We find that the convective WCB ascent leads to substantially stronger surface precipitation and the formation of graupel in the middle to upper troposphere, which is absent for the slantwise WCB category, indicating the key role of WCB-embedded convection for precipitation extremes. Compared to the slantwise WCB trajectories, the initial equivalent potential temperature of the convective WCB trajectories is higher, and the convective WCB trajectories originate from a region of larger potential instability, which gives rise to more intense cloud diabatic heating and stronger cross-isentropic ascent. Moreover, the signature of embedded convection is distinctly imprinted in the PV structure. The diabatically generated low-level positive PV anomalies, associated with a cyclonic circulation anomaly, are substantially stronger for the convective WCB trajectories. The slantwise WCB trajectories lead to the formation of a widespread region of low-PV air (that still have weakly positive PV values) in the upper troposphere, in agreement with previous studies. In contrast, the convective WCB trajectories form mesoscale horizontal PV dipoles at upper levels, with one pole reaching negative PV values. On a larger scale, these individual mesoscale PV anomalies can aggregate to elongated PV dipole bands extending from the convective updraft region, which are associated with coherent larger-scale circulation anomalies. An illustrative example of such a convectively generated PV dipole band shows that within around 10 h the negative PV pole is advected closer to the upper-level waveguide, where it strengthens the isentropic PV gradient and contributes to the formation of a jet streak. This suggests that the mesoscale PV anomalies produced by embedded convection upstream organize and persist for several hours and therefore can influence the synoptic-scale circulation. They thus can be dynamically relevant, influence the jet stream and (potentially) the downstream flow evolution, which are highly relevant aspects for medium-range weather forecast. Finally, our results imply that a distinction between slantwise and convective WCB trajectories is meaningful because the convective WCB trajectories are characterized by distinct properties. ISSN:2698-4016 ISSN:2698-4008 |
format |
Article in Journal/Newspaper |
author |
Oertel, Annika Boettcher, Maxi Joos, Hanna Sprenger, Michael Wernli, Heini |
spellingShingle |
Oertel, Annika Boettcher, Maxi Joos, Hanna Sprenger, Michael Wernli, Heini Potential vorticity structure of embedded convection in a warm conveyor belt and its relevance for large-scale dynamics |
author_facet |
Oertel, Annika Boettcher, Maxi Joos, Hanna Sprenger, Michael Wernli, Heini |
author_sort |
Oertel, Annika |
title |
Potential vorticity structure of embedded convection in a warm conveyor belt and its relevance for large-scale dynamics |
title_short |
Potential vorticity structure of embedded convection in a warm conveyor belt and its relevance for large-scale dynamics |
title_full |
Potential vorticity structure of embedded convection in a warm conveyor belt and its relevance for large-scale dynamics |
title_fullStr |
Potential vorticity structure of embedded convection in a warm conveyor belt and its relevance for large-scale dynamics |
title_full_unstemmed |
Potential vorticity structure of embedded convection in a warm conveyor belt and its relevance for large-scale dynamics |
title_sort |
potential vorticity structure of embedded convection in a warm conveyor belt and its relevance for large-scale dynamics |
publisher |
Copernicus |
publishDate |
2020 |
url |
https://hdl.handle.net/20.500.11850/456726 https://doi.org/10.3929/ethz-b-000456726 |
genre |
North Atlantic |
genre_facet |
North Atlantic |
op_source |
Weather and Climate Dynamics, 1 (1) |
op_relation |
info:eu-repo/semantics/altIdentifier/doi/10.5194/wcd-1-127-2020 info:eu-repo/grantAgreement/SNF/Projekte MINT/165941 http://hdl.handle.net/20.500.11850/456726 doi:10.3929/ethz-b-000456726 |
op_rights |
info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/4.0/ Creative Commons Attribution 4.0 International |
op_rightsnorm |
CC-BY |
op_doi |
https://doi.org/20.500.11850/456726 https://doi.org/10.3929/ethz-b-000456726 https://doi.org/10.5194/wcd-1-127-2020 |
_version_ |
1766137234809946112 |
spelling |
ftethz:oai:www.research-collection.ethz.ch:20.500.11850/456726 2023-05-15T17:37:21+02:00 Potential vorticity structure of embedded convection in a warm conveyor belt and its relevance for large-scale dynamics Oertel, Annika Boettcher, Maxi Joos, Hanna Sprenger, Michael Wernli, Heini 2020-04-09 application/application/pdf https://hdl.handle.net/20.500.11850/456726 https://doi.org/10.3929/ethz-b-000456726 en eng Copernicus info:eu-repo/semantics/altIdentifier/doi/10.5194/wcd-1-127-2020 info:eu-repo/grantAgreement/SNF/Projekte MINT/165941 http://hdl.handle.net/20.500.11850/456726 doi:10.3929/ethz-b-000456726 info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/4.0/ Creative Commons Attribution 4.0 International CC-BY Weather and Climate Dynamics, 1 (1) info:eu-repo/semantics/article info:eu-repo/semantics/publishedVersion 2020 ftethz https://doi.org/20.500.11850/456726 https://doi.org/10.3929/ethz-b-000456726 https://doi.org/10.5194/wcd-1-127-2020 2022-04-25T14:18:00Z Warm conveyor belts (WCBs) are important airstreams in extratropical cyclones. They can influence large-scale flow evolution by modifying the potential vorticity (PV) distribution during their cross-isentropic ascent. Although WCBs are typically described as slantwise-ascending and stratiform-cloud-producing airstreams, recent studies identified convective activity embedded within the large-scale WCB cloud band. However, the impacts of this WCB-embedded convection have not been investigated in detail. In this study, we systematically analyze the influence of embedded convection in an eastern North Atlantic WCB on the cloud and precipitation structure, on the PV distribution, and on larger-scale flow. For this reason, we apply online trajectories in a high-resolution convection-permitting simulation and perform a composite analysis to compare quasi-vertically ascending convective WCB trajectories with typical slantwise-ascending WCB trajectories. We find that the convective WCB ascent leads to substantially stronger surface precipitation and the formation of graupel in the middle to upper troposphere, which is absent for the slantwise WCB category, indicating the key role of WCB-embedded convection for precipitation extremes. Compared to the slantwise WCB trajectories, the initial equivalent potential temperature of the convective WCB trajectories is higher, and the convective WCB trajectories originate from a region of larger potential instability, which gives rise to more intense cloud diabatic heating and stronger cross-isentropic ascent. Moreover, the signature of embedded convection is distinctly imprinted in the PV structure. The diabatically generated low-level positive PV anomalies, associated with a cyclonic circulation anomaly, are substantially stronger for the convective WCB trajectories. The slantwise WCB trajectories lead to the formation of a widespread region of low-PV air (that still have weakly positive PV values) in the upper troposphere, in agreement with previous studies. In contrast, the convective WCB trajectories form mesoscale horizontal PV dipoles at upper levels, with one pole reaching negative PV values. On a larger scale, these individual mesoscale PV anomalies can aggregate to elongated PV dipole bands extending from the convective updraft region, which are associated with coherent larger-scale circulation anomalies. An illustrative example of such a convectively generated PV dipole band shows that within around 10 h the negative PV pole is advected closer to the upper-level waveguide, where it strengthens the isentropic PV gradient and contributes to the formation of a jet streak. This suggests that the mesoscale PV anomalies produced by embedded convection upstream organize and persist for several hours and therefore can influence the synoptic-scale circulation. They thus can be dynamically relevant, influence the jet stream and (potentially) the downstream flow evolution, which are highly relevant aspects for medium-range weather forecast. Finally, our results imply that a distinction between slantwise and convective WCB trajectories is meaningful because the convective WCB trajectories are characterized by distinct properties. ISSN:2698-4016 ISSN:2698-4008 Article in Journal/Newspaper North Atlantic ETH Zürich Research Collection |