Climate Variability of the Arctic from an Isentropic Potential Vorticity Perspective

The background state of the Arctic atmosphere under prolonged warming is analyzed by evaluating blended CFSR-CFSv2 reanalysis data from an isentropic lens, where potential temperature is used as the vertical coordinate and the principle dynamical framework is potential vorticity (PV). Since the quan...

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Bibliographic Details
Other Authors: Haynes, Brian Joshua (author), Chassignet, Eric P. (professor directing thesis), Bourassa, Mark Allan (committee member), Dukhovskoy, Dmitry (committee member), Sura, Philip (committee member), Florida State University (degree granting institution), College of Arts and Sciences (degree granting college), Department of Earth, Ocean, and Atmospheric Science (degree granting department)
Format: Master Thesis
Language:English
Published: Florida State University 2019
Subjects:
Meteorology
Arctic
Arctic Ocean
Beaufort Sea
Sea ice
Online Access:http://purl.flvc.org/fsu/fd/2019_Fall_Haynes_fsu_0071N_15583
https://diginole.lib.fsu.edu/islandora/object/fsu%3A759969/datastream/TN/view/Climate%20Variability%20of%20the%20Arctic%20from%20an%20Isentropic%20Potential%20Vorticity%20Perspective.jpg
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Summary:The background state of the Arctic atmosphere under prolonged warming is analyzed by evaluating blended CFSR-CFSv2 reanalysis data from an isentropic lens, where potential temperature is used as the vertical coordinate and the principle dynamical framework is potential vorticity (PV). Since the quantity is materially conserved along adiabatic, friction-less flow, PV can be used to describe the background vorticity and static stability as well as to give insight on how diabatic processes might alter this balance. Of particular interest is how the background state of the lower troposphere has evolved in recent years to become preferential to inducing anticyclonic wind stress at the Arctic ice-ocean surface. We compare the trends in Arctic PV to the Arctic Ocean Oscillation (AOO), which entered a phase of a dominantly anticyclonic circulation of the Beaufort Gyre (BG) in the mid-to-late 1990's and has persisted since. We find that PV has a relationship with sea surface height (SSH), which in turn can be used to quantify the index of the AOO, and that the strongest relationship occurs during the ice melt season. The reduced meridional thermal gradient during the ice melt season, here designated as the summer (JJA) and autumn (SON) seasons, allows for increased meridional transport of mid-latitude air masses. This is quantified by correlating melt season PV flux and the surface heat budget as well as wintertime geopotential height and zonal wind to connect the background environment preceding the peak Arctic Oscillation (AO) signal, which can enhance or suppress the typical sea level pressure (SLP) maximum that exists over the Beaufort Sea during this time. We find that positive meridional fluxes of PV during summer correlate with increased net shortwave fluxes at the surface and increased outgoing longwave fluxes in autumn. The relationship between the influx of low-latitude PV and the surface heat budget is consistent with previous works that demonstrate the role Arctic cyclones have on sea ice transport, which has ...

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