We use cookies to improve your experience, some are essential for the operation of this site.
About the cookies we use
Accept
Log in
ImportActions
Selections
0
Settings
View items
Field search
Subject search
Location search
Recent searches
Documentation
Quick start guide
Subject matches "PO - Physical Oceanography" or its children
Item
of 31
0
of
0
highlighted terms
No highlightable terms
Hide highlights
AssetActions
Feedback
Share via email
Share via email
Share via Facebook
Share via Twitter
Workflow
Illustration depicting the formation cycle of piteraq winds.
This item is active and ready to use
Illustration depicting the formation cycle of piteraq winds.
Illustration depicting the formation cycle of piteraq winds.
Comments
(0)
Main
Digital original
Analog original
Scientific
Use of image
Version
iBase ID
265169
Creator
Taylor, Eric S.
Title
Illustration depicting the formation cycle of piteraq winds.
Illustration depicting the formation cycle of piteraq winds.
Type
Animation
Audio
File
Illustration
Instructional
Still Image
Video
Illustration
Date
01/12/2016
File name
Piteraqs.jpg
Notes
Caption from Oceanus magazine, Vol. 51, No. 2, pg. 25: 1) The trigger for piteraqs seems to be low-pressure systems, or cyclones, that tend to form frequently to the east and southeast of Greenland. Cyclonic winds from the northwest push a reservoir of cold air that forms over the ice sheet, sending it downhill in a jolt. 2) When the cold air rushes downhill, it creates a mountain wave, which occurs along the stratified boundary between colder, denser air masses and warmer, more buoyant air masses. The lower layer of colder air is squeezed into a smaller volume and then accelerates out of its confines, rushing downward along the steep slopes. It breaks, like a big wave of water that collapses and crashes onto the shore, creating a lot of turbulence. 3) A second driving force for piteraqs is gravity, which accelerates the speed of anything falling downhill, even a mass of cold air. Air speeds pick up, increasing the strength of the piteraq winds. 4) Other aspects of topography play a role in driving piteraqs. Tasiilaq is located inside a valley, which funnels the flow of cold air into a smaller and smaller space, increasing its velocity over the ice sheet and toward the fjord. By the time the air reaches the fjord, it shoots out at top speed.
Caption from Oceanus magazine, Vol. 51, No. 2, pg. 25:
1) The trigger for piteraqs seems to be low-pressure systems, or cyclones, that tend to form frequently to the east and southeast of Greenland. Cyclonic winds from the northwest push a reservoir of cold air that forms over the ice sheet, sending it downhill in a jolt.
2) When the cold air rushes downhill, it creates a mountain wave, which occurs along the stratified boundary between colder, denser air masses and warmer, more buoyant air masses. The lower layer of colder air is squeezed into a smaller volume and then accelerates out of its confines, rushing downward along the steep slopes. It breaks, like a big wave of water that collapses and crashes onto the shore, creating a lot of turbulence.
3) A second driving force for piteraqs is gravity, which accelerates the speed of anything falling downhill, even a mass of cold air. Air speeds pick up, increasing the strength of the piteraq winds.
4) Other aspects of topography play a role in driving piteraqs. Tasiilaq is located inside a valley, which funnels the flow of cold air into a smaller and smaller space, increasing its velocity over the ice sheet and toward the fjord. By the time the air reaches the fjord, it shoots out at top speed.
Credit line
© Shane Gross/Greenpeace
© Woods Hole Oceanographic Institution
Adinah Barnett
Adobe Farmhouse Photography
Alamy Stock Photo
Courtesy of National Aeronautics and Space Administration
Getty Images/iStockphoto
Illustration by Eric S. Taylor, WHOI Creative
Illustration by Jack Cook
Illustration by Jayne Doucette
Illustration by Natalie Renier, WHOI Creative
Marine Imaging Technologies, LLC © Woods Hole Oceanographic Institution
Photo by Amy Apprill
Photo by Craig LaPlante
Photo by Daniel Hentz
Photo by Danielle Fino
Photo by Darlene Trew Crist
Photo by Elise Hugus
Photo by Hannah Piecuch
Photo by Jayne Doucette
Photo by Katherine Spencer Joyce
Photo by Ken Kostel
Photo by Marley L. Parker
Photo by Matthew Barton
Photo by ML Parker
Photo by Rachel Mann
Photo by Rebecca Travis
Photo by Sean Patrick Whelan
Photo by Tina Thomas
Photo by Tom Kleindinst
Photo by Véronique LaCapra
Photo courtesy of Woods Hole Oceanographic Institution Archives
Photographie : @alexis.rosenfeld
ROV SuBastian / Schmidt Ocean In
Video by Craig LaPlante
Video by Danielle Fino
Video by Hannah Piecuch
Video by Jayne Doucette
Video by Ken Kostel
Video by Matthew Barton
WHOI Creative © Woods Hole Oceanographic Institution
-- Other --
Illustration by Eric S. Taylor, WHOI Creative
Copyright statement
© Scripps Institution of Oceanography at UC San Diego
© 2021 Woods Hole Oceanographic Institution, all rights reserved
© 2023 Woods Hole Oceanographic Institution, all rights reserved
© Alexis Rosenfeld
© Bearwalk Cinema
© C. A. Linder
© Cape Cod Times
© Consortium for Ocean Leadership
© Daniel P. Zitterbart
© Figure 8 Studio
© Luis Lamar
© Mote Marine Laboratory
© National Aeronautics and Space Administration
© National Oceanic and Atmospheric Administration
© Shane Gross/Greenpeace
© Woods Hole Oceanographic Institution
2012 Backyard Productions LLC
2018 - The Boston Globe
ADOBE FARMHOUSE PHOTOGRAPHY2023
Alan Chung © 2022
Alfred-Wegener-Institut / Michael Gutsche (CC-BY 4.0)
Amy Van Cise/www.cascadiaresearch.org
Art Wager
Aurora Lampson
Austin Greene Photography
Avatar Alliance Foundation
bjoernkils@gmail.com +1.732.586.7394 www.NewYorkMediaBoat.com
CC BY-SA Troy Sankey
Commonwealth of Australia (GBRMPA)
Copyright (c) 2012 Vanderhaegen Bart
Copyright © 2010 David M. Lawrence
Copyright 2002
Copyright 2007 Jeff Yonover
Copyright 2019 to Nick Valentine
Copyright Jim Stringer
Copyright,
Copyright: Jenouvrier - WHOI
Copyright: Peter Kimball
Credit: Universal Images Group North America LLC / Alamy Stock Photo
Croy Carlin
Dee Sullivan
Franz Mahr
FtLaudGirl
Hasselblad H6D
Henley Spiers
Image courtesy of NOAA Ocean Exploration, Deep Connections 2019.
Jeff Yonover 2015
Lewis Burnett
Luis Lamar
Marley Parker/WHOI
Martin Schiller http://martin-schiller.de
MINFIN PHOTOGRAPHY
Moorefam
NautilusLive/Ocean Exploration Trust
Paul Caiger
Photo by Chris Linder, WHOI
Rachael Talibart 2016
Robert E. Todd
roger fishman 2019
SP Whelan
thexfilephoto
Thomas A D Slager
Tom Shlesinger
UnderCurrent Productions
Unless otherwise noted (copyrighted material for example), information presented on this World Wide Web site is considered publi
WHOI
WHOI 2005
WHOI/ML Parker
Woods Hole Oceanographic Institution
Woods Hole Oceanographic Institution.
www.joshuaqualls.com
-- Other --
© Woods Hole Oceanographic Institution
Other restrictions
Provenance
URL
Orientation
Portrait
Resolution (DPI)
72
File name
Piteraqs.jpg
File type
Image
File extension
JPEG
File size
1.43MB
Height
2569px
Width
971px
Uploaded by
jdoucette
Uploaded on
2016-02-18 00:00:00
Views
668
Analog file name
Analog source type
Analog source notes
Archives location
Analog negative number
Latitude
Longitude
Time (hh:mm:ss)
Depth
Altitude
Heading
Pitch
Roll
Licensing information
Legacy usage
etaylor: Oceanus magazine, Vol. 51, No. 2, pg. 25
etaylor: Oceanus magazine, Vol. 51, No. 2, pg. 25
Version
Labels
Subjects
Organization
>
Departments
>
PO - Physical Oceanography
remove
Topics
>
Meteorology
remove
Assign subject
Remove all subjects
This item includes these files
Image
Collections
Selections
0
Open full page
Clear all
Search within
By field
By subject
By location
By folder / collection
By recent searches
Print
Export data
Collection
Edit
Lock
Workflow