elib
DLR-Header
DLR-Logo -> http://www.dlr.de
DLR Portal Home | Impressum | Datenschutz | Kontakt | English
Schriftgröße: [-] Text [+]

On the magnitude and sensitivity of the quasi-biennial oscillation response to a tropical volcanic eruption

Brown, Flossie und Marshall, Lauren und Haynes, Peter H. und Garcia, Rolando R. und Birner, Thomas und Schmidt, Anja (2023) On the magnitude and sensitivity of the quasi-biennial oscillation response to a tropical volcanic eruption. Atmospheric Chemistry and Physics, 23 (9), Seiten 5335-5353. Copernicus Publications. doi: 10.5194/acp-23-5335-2023. ISSN 1680-7316.

[img] PDF - Verlagsversion (veröffentlichte Fassung)
11MB

Offizielle URL: https://dx.doi.org/10.5194/acp-23-5335-2023

Kurzfassung

Volcanic eruptions that inject sulfur dioxide into the stratosphere have the potential to alter largescale circulation patterns, such as the quasi-biennial oscillation (QBO), which can affect weather and transport of chemical species. Here, we conduct simulations of tropical volcanic eruptions using the UM-UKCA aerosolclimate model with an explicit representation of the QBO. Eruptions emitting 60 Tg of SO2 (i.e. the magnitude of the 1815 Mt. Tambora eruption) and 15 Tg of SO2 (i.e. the magnitude of the 1991 Mt. Pinatubo eruption) were initiated at the Equator during two different QBO states. We show that tropical eruptions delay the progression of the QBO phases, with the magnitude of the delay dependent on the initial wind shear in the lower stratosphere and a much longer delay when the shear is easterly than when it is westerly. The QBO response in our model is driven by vertical advection of momentum by the stronger tropical upwelling caused by heating due to the increased volcanic sulfate aerosol loading. Direct aerosol-induced warming with subsequent thermal wind adjustment, as proposed by previous studies, is found to only play a secondary role. This interpretation of the response is supported by comparison with a simple dynamical model. The dependence of the magnitude of the response on the initial QBO state results from differences in the QBO secondary circulation. In the easterly shear zone of the QBO, the vertical component of the secondary circulation is upward and reinforces the anomalous upwelling driven by volcanic aerosol heating, whereas in the westerly shear zone the vertical component is downward and opposes the aerosol-induced upwelling. We also find a change in the latitudinal structure of the QBO, with the westerly phase of the QBO strengthening in the hemisphere with the lowest sulfate aerosol burden. Overall, our study suggests that tropical eruptions of Pinatubo magnitude or larger could force changes to the progression of the QBO, with particularly disruptive outcomes for the QBO if the eruption occurs during the easterly QBOshear.

elib-URL des Eintrags:https://elib.dlr.de/198394/
Dokumentart:Zeitschriftenbeitrag
Titel:On the magnitude and sensitivity of the quasi-biennial oscillation response to a tropical volcanic eruption
Autoren:
AutorenInstitution oder E-Mail-AdresseAutoren-ORCID-iDORCID Put Code
Brown, FlossieUniversity of Exeter, Exeter, UKNICHT SPEZIFIZIERTNICHT SPEZIFIZIERT
Marshall, LaurenUniversity of Cambridge, Cambridge, UKhttps://orcid.org/0000-0003-1471-9481NICHT SPEZIFIZIERT
Haynes, Peter H.University of Cambridge, Cambridge, UKNICHT SPEZIFIZIERTNICHT SPEZIFIZIERT
Garcia, Rolando R.NCAR, Boulder, CO, USANICHT SPEZIFIZIERTNICHT SPEZIFIZIERT
Birner, ThomasLMU München, MünchenNICHT SPEZIFIZIERTNICHT SPEZIFIZIERT
Schmidt, AnjaDLR, IPANICHT SPEZIFIZIERTNICHT SPEZIFIZIERT
Datum:12 Mai 2023
Erschienen in:Atmospheric Chemistry and Physics
Referierte Publikation:Ja
Open Access:Ja
Gold Open Access:Ja
In SCOPUS:Ja
In ISI Web of Science:Ja
Band:23
DOI:10.5194/acp-23-5335-2023
Seitenbereich:Seiten 5335-5353
Verlag:Copernicus Publications
ISSN:1680-7316
Status:veröffentlicht
Stichwörter:QBO
HGF - Forschungsbereich:Luftfahrt, Raumfahrt und Verkehr
HGF - Programm:Raumfahrt
HGF - Programmthema:keine Zuordnung
DLR - Schwerpunkt:Raumfahrt
DLR - Forschungsgebiet:R - keine Zuordnung
DLR - Teilgebiet (Projekt, Vorhaben):R - keine Zuordnung
Standort: Oberpfaffenhofen
Institute & Einrichtungen:Institut für Physik der Atmosphäre > Erdsystem-Modellierung
Hinterlegt von: Schmidt, Anja
Hinterlegt am:24 Okt 2023 08:04
Letzte Änderung:04 Dez 2023 11:32

Nur für Mitarbeiter des Archivs: Kontrollseite des Eintrags

Blättern
Suchen
Hilfe & Kontakt
Informationen
electronic library verwendet EPrints 3.3.12
Gestaltung Webseite und Datenbank: Copyright © Deutsches Zentrum für Luft- und Raumfahrt (DLR). Alle Rechte vorbehalten.