Impact of Stratospheric Volcanic Aerosols on Age-of-Air and Transport of Long-Lived Species

Impact of Stratospheric Volcanic Aerosols on Age-of-Air and Transport of Long-Lived Species

The radiative perturbation associated to stratospheric aerosols from major explosive volcanic eruptions may induce significant changes in stratospheric dynamics. The aerosol heating rates warm up the lower stratosphere and cause a westerly wind anomaly, with additional tropical upwelling. Large scal...

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Main Authors: Giovanni Pitari, Irene Cionni, Glauco Di Genova, Daniele Visioni, Ilaria Gandolfi, Eva Mancini
Format: Article
Language:English
Published: MDPI AG 2016-11-01
Series:Atmosphere
Subjects:
climate-chemistry model
explosive volcanic eruptions
sulfate aerosols
stratospheric dynamics
long-lived species transport
stratospheric age-of-air
Online Access:http://www.mdpi.com/2073-4433/7/11/149
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spelling doaj-9a33e8d7e8ad4fc189aed20cfab33c9e2020-11-24T23:46:53ZengMDPI AGAtmosphere2073-44332016-11-0171114910.3390/atmos7110149atmos7110149Impact of Stratospheric Volcanic Aerosols on Age-of-Air and Transport of Long-Lived SpeciesGiovanni Pitari0Irene Cionni1Glauco Di Genova2Daniele Visioni3Ilaria Gandolfi4Eva Mancini5Giovanni Pitari, Department of Physical and Chemical Sciences, Università dell’Aquila, 67100 L’Aquila, ItalyEnea, Ente per le Nuove Tecnologie, L’Energia e L’Ambiente, 00123 Roma, ItalyGiovanni Pitari, Department of Physical and Chemical Sciences, Università dell’Aquila, 67100 L’Aquila, ItalyGiovanni Pitari, Department of Physical and Chemical Sciences, Università dell’Aquila, 67100 L’Aquila, ItalyGiovanni Pitari, Department of Physical and Chemical Sciences, Università dell’Aquila, 67100 L’Aquila, ItalyGiovanni Pitari, Department of Physical and Chemical Sciences, Università dell’Aquila, 67100 L’Aquila, ItalyThe radiative perturbation associated to stratospheric aerosols from major explosive volcanic eruptions may induce significant changes in stratospheric dynamics. The aerosol heating rates warm up the lower stratosphere and cause a westerly wind anomaly, with additional tropical upwelling. Large scale transport of stratospheric trace species may be perturbed as a consequence of this intensified Brewer–Dobson circulation. The radiatively forced changes of the stratospheric circulation during the first two years after the eruption of Mt. Pinatubo (June 1991) may help explain the observed trend decline of long-lived greenhouse gases at surface stations (approximately −8 and −0.4 ppbv/year for CH4 and N2O, respectively). This decline is partly driven by the increased mid- to high-latitude downward flux at the tropopause and also by an increased isolation of the tropical pipe in the vertical layer near the tropopause, with reduced horizontal eddy mixing. Results from a climate-chemistry coupled model are shown for both long-lived trace species and the stratospheric age-of-air. The latter results to be younger by approximately 0.5 year at 30 hPa for 3–4 years after the June 1991 Pinatubo eruption, as a result of the volcanic aerosols radiative perturbation and is consistent with independent estimates based on long time series of in situ profile measurements of SF6 and CO2. Younger age of air is also calculated after Agung, El Chichón and Ruiz eruptions, as well as negative anomalies of the N2O growth rate at the extratropical tropopause layer. This type of analysis is made comparing the results of two ensembles of model simulations (1960–2005), one including stratospheric volcanic aerosols and their radiative interactions and a reference case where the volcanic aerosols do not interact with solar and planetary radiation.http://www.mdpi.com/2073-4433/7/11/149climate-chemistry modelexplosive volcanic eruptionssulfate aerosolsstratospheric dynamicslong-lived species transportstratospheric age-of-air
collection DOAJ
language English
format Article
sources DOAJ
author Giovanni Pitari
Irene Cionni
Glauco Di Genova
Daniele Visioni
Ilaria Gandolfi
Eva Mancini
spellingShingle Giovanni Pitari
Irene Cionni
Glauco Di Genova
Daniele Visioni
Ilaria Gandolfi
Eva Mancini
Impact of Stratospheric Volcanic Aerosols on Age-of-Air and Transport of Long-Lived Species
Atmosphere
climate-chemistry model
explosive volcanic eruptions
sulfate aerosols
stratospheric dynamics
long-lived species transport
stratospheric age-of-air
author_facet Giovanni Pitari
Irene Cionni
Glauco Di Genova
Daniele Visioni
Ilaria Gandolfi
Eva Mancini
author_sort Giovanni Pitari
title Impact of Stratospheric Volcanic Aerosols on Age-of-Air and Transport of Long-Lived Species
title_short Impact of Stratospheric Volcanic Aerosols on Age-of-Air and Transport of Long-Lived Species
title_full Impact of Stratospheric Volcanic Aerosols on Age-of-Air and Transport of Long-Lived Species
title_fullStr Impact of Stratospheric Volcanic Aerosols on Age-of-Air and Transport of Long-Lived Species
title_full_unstemmed Impact of Stratospheric Volcanic Aerosols on Age-of-Air and Transport of Long-Lived Species
title_sort impact of stratospheric volcanic aerosols on age-of-air and transport of long-lived species
publisher MDPI AG
series Atmosphere
issn 2073-4433
publishDate 2016-11-01
description The radiative perturbation associated to stratospheric aerosols from major explosive volcanic eruptions may induce significant changes in stratospheric dynamics. The aerosol heating rates warm up the lower stratosphere and cause a westerly wind anomaly, with additional tropical upwelling. Large scale transport of stratospheric trace species may be perturbed as a consequence of this intensified Brewer–Dobson circulation. The radiatively forced changes of the stratospheric circulation during the first two years after the eruption of Mt. Pinatubo (June 1991) may help explain the observed trend decline of long-lived greenhouse gases at surface stations (approximately −8 and −0.4 ppbv/year for CH4 and N2O, respectively). This decline is partly driven by the increased mid- to high-latitude downward flux at the tropopause and also by an increased isolation of the tropical pipe in the vertical layer near the tropopause, with reduced horizontal eddy mixing. Results from a climate-chemistry coupled model are shown for both long-lived trace species and the stratospheric age-of-air. The latter results to be younger by approximately 0.5 year at 30 hPa for 3–4 years after the June 1991 Pinatubo eruption, as a result of the volcanic aerosols radiative perturbation and is consistent with independent estimates based on long time series of in situ profile measurements of SF6 and CO2. Younger age of air is also calculated after Agung, El Chichón and Ruiz eruptions, as well as negative anomalies of the N2O growth rate at the extratropical tropopause layer. This type of analysis is made comparing the results of two ensembles of model simulations (1960–2005), one including stratospheric volcanic aerosols and their radiative interactions and a reference case where the volcanic aerosols do not interact with solar and planetary radiation.
topic climate-chemistry model
explosive volcanic eruptions
sulfate aerosols
stratospheric dynamics
long-lived species transport
stratospheric age-of-air
url http://www.mdpi.com/2073-4433/7/11/149
work_keys_str_mv AT giovannipitari impactofstratosphericvolcanicaerosolsonageofairandtransportoflonglivedspecies
AT irenecionni impactofstratosphericvolcanicaerosolsonageofairandtransportoflonglivedspecies
AT glaucodigenova impactofstratosphericvolcanicaerosolsonageofairandtransportoflonglivedspecies
AT danielevisioni impactofstratosphericvolcanicaerosolsonageofairandtransportoflonglivedspecies
AT ilariagandolfi impactofstratosphericvolcanicaerosolsonageofairandtransportoflonglivedspecies
AT evamancini impactofstratosphericvolcanicaerosolsonageofairandtransportoflonglivedspecies
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