El Niño Southern Oscillation teleconnections and their effects on the Amundsen Sea region

El Niño Southern Oscillation events have global implications both climatologically and socio-economically. One such climatological teleconnection is manifested in the Amundsen Sea region (ASR). The Amundsen sea low (ASL) is the dominant low pressure system located around the ASR and is important to...

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Bibliographic Details
Main Author: Yiu, Yu Yeung Scott
Format: Thesis
Language:English
Published: Apollo - University of Cambridge Repository 2018
Subjects:
El Niño
Teleconnections
Amundsen Sea Low
Amundsen sea region
Tropical > extra tropical teleconnections
Pacific South America pattern
Southern Annular mode
Seasonality
ENSO > Amundsen sea region teleconnection
ENSO > Amundsen sea low teleconnection
Linearity
Antarctic
Austral
Amundsen Sea
Pacific
Antarc*
Antarctica
British Antarctic Survey
Online Access:https://dx.doi.org/10.17863/cam.23516
https://www.repository.cam.ac.uk/handle/1810/276236
id ftdatacite:10.17863/cam.23516
record_format openpolar
spelling ftdatacite:10.17863/cam.23516 2023-05-15T13:23:38+02:00 El Niño Southern Oscillation teleconnections and their effects on the Amundsen Sea region Yiu, Yu Yeung Scott 2018 https://dx.doi.org/10.17863/cam.23516 https://www.repository.cam.ac.uk/handle/1810/276236 en eng Apollo - University of Cambridge Repository All copyrighted images have been redacted. https://www.rioxx.net/licenses/all-rights-reserved/ All Rights Reserved All rights reserved El Niño Teleconnections Amundsen Sea Low Amundsen sea region Tropical -- extra tropical teleconnections Pacific South America pattern Southern Annular mode Seasonality ENSO--Amundsen sea region teleconnection ENSO--Amundsen sea low teleconnection Linearity Text Thesis article-journal ScholarlyArticle 2018 ftdatacite https://doi.org/10.17863/cam.23516 2021-11-05T12:55:41Z El Niño Southern Oscillation events have global implications both climatologically and socio-economically. One such climatological teleconnection is manifested in the Amundsen Sea region (ASR). The Amundsen sea low (ASL) is the dominant low pressure system located around the ASR and is important to the climate of Western Antarctica. Therefore, it is important to understand the ASL and any phenomena that may affect it. This thesis focuses on the ENSO--ASR teleconnection under El Niño conditions and the mechanism behind it. The ENSO--ASR teleconnection was explored using the UM version 8.4 (HadGEM3) model. Time--slice experiments with various magnitudes of idealised perpetual ENSO events are imposed. Two sets of `switch on' experiments in which tropical Pacific SSTs were ramped up were also carried out to investigate the transient nature of the teleconnection. The seasonality of the ENSO--ASR teleconnection is known from previous studies to be stronger in winter compared to summer. The mechanism behind the seasonality was explored using the time--slice experiments. The seasonality is found to originate from the seasonal differences in the Southern Hemispheric jets. As the subtropical jet is only present in austral winter, Rossby wave source anomalies can only be generated in the mid--latitudes in winter. Furthermore, the propagation of the Rossby waves is not possible in summer due to the strong polar front jet. The lack of the source and propagation in summer explains the weaker ENSO--ASR teleconnection. A flowchart summarising the mechanism was created and then verified by the transient runs. The linearity of the ENSO--ASR teleconnection within El Niño has not been previously investigated. This is mainly due to insufficient reanalysis data available to overcome the high internal variability in the ASR. In this thesis, the linearity of the teleconnection under El Niño is studied using the time--slice runs. The results indicate linearity (within errorbars) for both the summer and winter seasons up to historically maximum El Niños. However, under extreme El Niños (beyond historic records) in winter, the teleconnection is no longer linear. The UPSCALE dataset was used to investigate the effects of horizontal resolution on the simulation of the ASL climatological state and the ENSO--ASR teleconnection. The UPSCALE dataset consists of ensembles of HadGEM3 simulations at three different horizontal resolutions. The high resolution model was found to better simulate the ASL while the low resolution model was found to better simulate the ENSO--ASR teleconnection. : This project was funded by NERC and ERC and is hosted in the University of Cambridge by a grant joint with the British Antarctic Survey. Thesis Amundsen Sea Antarc* Antarctic Antarctica British Antarctic Survey DataCite Metadata Store (German National Library of Science and Technology) Antarctic Austral Amundsen Sea Pacific
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language English
topic El Niño
Teleconnections
Amundsen Sea Low
Amundsen sea region
Tropical -- extra tropical teleconnections
Pacific South America pattern
Southern Annular mode
Seasonality
ENSO--Amundsen sea region teleconnection
ENSO--Amundsen sea low teleconnection
Linearity
spellingShingle El Niño
Teleconnections
Amundsen Sea Low
Amundsen sea region
Tropical -- extra tropical teleconnections
Pacific South America pattern
Southern Annular mode
Seasonality
ENSO--Amundsen sea region teleconnection
ENSO--Amundsen sea low teleconnection
Linearity
Yiu, Yu Yeung Scott
El Niño Southern Oscillation teleconnections and their effects on the Amundsen Sea region
topic_facet El Niño
Teleconnections
Amundsen Sea Low
Amundsen sea region
Tropical -- extra tropical teleconnections
Pacific South America pattern
Southern Annular mode
Seasonality
ENSO--Amundsen sea region teleconnection
ENSO--Amundsen sea low teleconnection
Linearity
description El Niño Southern Oscillation events have global implications both climatologically and socio-economically. One such climatological teleconnection is manifested in the Amundsen Sea region (ASR). The Amundsen sea low (ASL) is the dominant low pressure system located around the ASR and is important to the climate of Western Antarctica. Therefore, it is important to understand the ASL and any phenomena that may affect it. This thesis focuses on the ENSO--ASR teleconnection under El Niño conditions and the mechanism behind it. The ENSO--ASR teleconnection was explored using the UM version 8.4 (HadGEM3) model. Time--slice experiments with various magnitudes of idealised perpetual ENSO events are imposed. Two sets of `switch on' experiments in which tropical Pacific SSTs were ramped up were also carried out to investigate the transient nature of the teleconnection. The seasonality of the ENSO--ASR teleconnection is known from previous studies to be stronger in winter compared to summer. The mechanism behind the seasonality was explored using the time--slice experiments. The seasonality is found to originate from the seasonal differences in the Southern Hemispheric jets. As the subtropical jet is only present in austral winter, Rossby wave source anomalies can only be generated in the mid--latitudes in winter. Furthermore, the propagation of the Rossby waves is not possible in summer due to the strong polar front jet. The lack of the source and propagation in summer explains the weaker ENSO--ASR teleconnection. A flowchart summarising the mechanism was created and then verified by the transient runs. The linearity of the ENSO--ASR teleconnection within El Niño has not been previously investigated. This is mainly due to insufficient reanalysis data available to overcome the high internal variability in the ASR. In this thesis, the linearity of the teleconnection under El Niño is studied using the time--slice runs. The results indicate linearity (within errorbars) for both the summer and winter seasons up to historically maximum El Niños. However, under extreme El Niños (beyond historic records) in winter, the teleconnection is no longer linear. The UPSCALE dataset was used to investigate the effects of horizontal resolution on the simulation of the ASL climatological state and the ENSO--ASR teleconnection. The UPSCALE dataset consists of ensembles of HadGEM3 simulations at three different horizontal resolutions. The high resolution model was found to better simulate the ASL while the low resolution model was found to better simulate the ENSO--ASR teleconnection. : This project was funded by NERC and ERC and is hosted in the University of Cambridge by a grant joint with the British Antarctic Survey.
format Thesis
author Yiu, Yu Yeung Scott
author_facet Yiu, Yu Yeung Scott
author_sort Yiu, Yu Yeung Scott
title El Niño Southern Oscillation teleconnections and their effects on the Amundsen Sea region
title_short El Niño Southern Oscillation teleconnections and their effects on the Amundsen Sea region
title_full El Niño Southern Oscillation teleconnections and their effects on the Amundsen Sea region
title_fullStr El Niño Southern Oscillation teleconnections and their effects on the Amundsen Sea region
title_full_unstemmed El Niño Southern Oscillation teleconnections and their effects on the Amundsen Sea region
title_sort el niño southern oscillation teleconnections and their effects on the amundsen sea region
publisher Apollo - University of Cambridge Repository
publishDate 2018
url https://dx.doi.org/10.17863/cam.23516
https://www.repository.cam.ac.uk/handle/1810/276236
geographic Antarctic
Austral
Amundsen Sea
Pacific
geographic_facet Antarctic
Austral
Amundsen Sea
Pacific
genre Amundsen Sea
Antarc*
Antarctic
Antarctica
British Antarctic Survey
genre_facet Amundsen Sea
Antarc*
Antarctic
Antarctica
British Antarctic Survey
op_rights All copyrighted images have been redacted.
https://www.rioxx.net/licenses/all-rights-reserved/
All Rights Reserved
All rights reserved
op_doi https://doi.org/10.17863/cam.23516
_version_ 1766373644000296960

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