Can Mountain Waves Contribute to Damaging Winds Far Away from the Lee Slope?

On 25 December 2016, a 984-hPa cyclone departed Colorado and moved onto the Northern Plains, drawing a nearby Arctic front into the circulation and wrapping it cyclonically around the equatorward side of the cyclone. A 130-km wide and 850-km long swath of surface winds exceeding 25 m s-1 originated...

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Published in:Weather and Forecasting
Main Authors: Kelley, Jeffrey D., Schultz, David, Schumacher, Russ S., Durran, Dale R.
Format: Article in Journal/Newspaper
Language:English
Published: 2019
Subjects:
Arctic
Online Access:https://research.manchester.ac.uk/en/publications/7355a76c-b214-4e10-9344-d40e76420a0b
https://doi.org/10.1175/WAF-D-18-0207.1
https://pure.manchester.ac.uk/ws/files/131897198/WAF_D_18_0207_Manuscript.pdf
id ftumanchesterpub:oai:pure.atira.dk:publications/7355a76c-b214-4e10-9344-d40e76420a0b
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spelling ftumanchesterpub:oai:pure.atira.dk:publications/7355a76c-b214-4e10-9344-d40e76420a0b 2023-11-12T04:11:07+01:00 Can Mountain Waves Contribute to Damaging Winds Far Away from the Lee Slope? Kelley, Jeffrey D. Schultz, David Schumacher, Russ S. Durran, Dale R. 2019 application/pdf https://research.manchester.ac.uk/en/publications/7355a76c-b214-4e10-9344-d40e76420a0b https://doi.org/10.1175/WAF-D-18-0207.1 https://pure.manchester.ac.uk/ws/files/131897198/WAF_D_18_0207_Manuscript.pdf eng eng info:eu-repo/semantics/openAccess Kelley , J D , Schultz , D , Schumacher , R S & Durran , D R 2019 , ' Can Mountain Waves Contribute to Damaging Winds Far Away from the Lee Slope? ' , Weather and Forecasting . https://doi.org/10.1175/WAF-D-18-0207.1 article 2019 ftumanchesterpub https://doi.org/10.1175/WAF-D-18-0207.1 2023-10-30T09:16:46Z On 25 December 2016, a 984-hPa cyclone departed Colorado and moved onto the Northern Plains, drawing a nearby Arctic front into the circulation and wrapping it cyclonically around the equatorward side of the cyclone. A 130-km wide and 850-km long swath of surface winds exceeding 25 m s-1 originated underneath the comma head of the lee cyclone and followed the track of the Arctic front from Colorado to Minnesota. These strong winds formed in association with a downslope windstorm and mountain wave over Colorado and Wyoming, producing an elevated jet of strong winds. Central to the distribution of winds in this case is the Arctic air mass, which both shielded the elevated winds from surface friction behind the front and facilitated the mixing of the elevated jet down to the surface just behind the Arctic front, due to steep lapse rates associated with cold-air advection. The intense circulation south of the cyclone center transported the Arctic front and the elevated jet away from the mountains and out across Great Plains. This case is compared to an otherwise similar cyclone from 28–29 February 2012 in which a downslope windstorm occurred, but no surface mesoscale wind maximum formed due to the absence of a well-defined Arctic front and post-frontal stable layer. Despite the superficial similarities of this surface wind maximum to a sting jet (e.g., origin in the midtroposphere within the comma head of the cyclone, descent evaporating the comma head, acceleration to the top of the boundary layer, and an existence separate from the cold conveyor belt), this swath of winds was not caused by a sting jet. Article in Journal/Newspaper Arctic The University of Manchester: Research Explorer Weather and Forecasting 34 6 2045 2065
institution Open Polar
collection The University of Manchester: Research Explorer
op_collection_id ftumanchesterpub
language English
description On 25 December 2016, a 984-hPa cyclone departed Colorado and moved onto the Northern Plains, drawing a nearby Arctic front into the circulation and wrapping it cyclonically around the equatorward side of the cyclone. A 130-km wide and 850-km long swath of surface winds exceeding 25 m s-1 originated underneath the comma head of the lee cyclone and followed the track of the Arctic front from Colorado to Minnesota. These strong winds formed in association with a downslope windstorm and mountain wave over Colorado and Wyoming, producing an elevated jet of strong winds. Central to the distribution of winds in this case is the Arctic air mass, which both shielded the elevated winds from surface friction behind the front and facilitated the mixing of the elevated jet down to the surface just behind the Arctic front, due to steep lapse rates associated with cold-air advection. The intense circulation south of the cyclone center transported the Arctic front and the elevated jet away from the mountains and out across Great Plains. This case is compared to an otherwise similar cyclone from 28–29 February 2012 in which a downslope windstorm occurred, but no surface mesoscale wind maximum formed due to the absence of a well-defined Arctic front and post-frontal stable layer. Despite the superficial similarities of this surface wind maximum to a sting jet (e.g., origin in the midtroposphere within the comma head of the cyclone, descent evaporating the comma head, acceleration to the top of the boundary layer, and an existence separate from the cold conveyor belt), this swath of winds was not caused by a sting jet.
format Article in Journal/Newspaper
author Kelley, Jeffrey D.
Schultz, David
Schumacher, Russ S.
Durran, Dale R.
spellingShingle Kelley, Jeffrey D.
Schultz, David
Schumacher, Russ S.
Durran, Dale R.
Can Mountain Waves Contribute to Damaging Winds Far Away from the Lee Slope?
author_facet Kelley, Jeffrey D.
Schultz, David
Schumacher, Russ S.
Durran, Dale R.
author_sort Kelley, Jeffrey D.
title Can Mountain Waves Contribute to Damaging Winds Far Away from the Lee Slope?
title_short Can Mountain Waves Contribute to Damaging Winds Far Away from the Lee Slope?
title_full Can Mountain Waves Contribute to Damaging Winds Far Away from the Lee Slope?
title_fullStr Can Mountain Waves Contribute to Damaging Winds Far Away from the Lee Slope?
title_full_unstemmed Can Mountain Waves Contribute to Damaging Winds Far Away from the Lee Slope?
title_sort can mountain waves contribute to damaging winds far away from the lee slope?
publishDate 2019
url https://research.manchester.ac.uk/en/publications/7355a76c-b214-4e10-9344-d40e76420a0b
https://doi.org/10.1175/WAF-D-18-0207.1
https://pure.manchester.ac.uk/ws/files/131897198/WAF_D_18_0207_Manuscript.pdf
genre Arctic
genre_facet Arctic
op_source Kelley , J D , Schultz , D , Schumacher , R S & Durran , D R 2019 , ' Can Mountain Waves Contribute to Damaging Winds Far Away from the Lee Slope? ' , Weather and Forecasting . https://doi.org/10.1175/WAF-D-18-0207.1
op_rights info:eu-repo/semantics/openAccess
op_doi https://doi.org/10.1175/WAF-D-18-0207.1
container_title Weather and Forecasting
container_volume 34
container_issue 6
container_start_page 2045
op_container_end_page 2065
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