The Persistently Variable “Background” Stratospheric Aerosol Layer and Global Climate Change

Solomon, Susan; Daniel, J. S.; Neely, Ryan R.; Vernier, Jean‐Paul; Dutton, Ellsworth G; Thomason, L. W.

doi:10.1126/science.1206027

Cited by 548 publications

(593 citation statements)

References 26 publications

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“…Their effect is visible in the increase of the stratospheric aerosol layer that has occurred since 2002 after a period with little volcanic influence. This increase in the stratospheric aerosol load has also been observed in other data sets, however, anthropogenic influence cannot be ruled out (Hofmann et al, 2009;Solomon et al, 2011).…”

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confidence: 51%

“…However studies indicate that OCS is not enough to explain the observed aerosol load (Chin and Davis, 1995), and direct transport of SO 2 or sulphate aerosol have been suggested as important contributions to stratospheric aerosol (Pitari et al, 2002;Myhre et al, 2004). Volcanic injections however makes it difficult to determine the background state of the stratospheric aerosol layer (Solomon et al, 2011), and thereby the importance of different sources for its production. A carbonaceous component of the UT/LMS aerosol was identified by Murphy et al (1998), which was subsequently found to be a large fraction of the aerosol (Nguyen et al, 2008;Murphy et al, 2007).…”

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confidence: 99%

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Composition and evolution of volcanic aerosol from eruptions of Kasatochi, Sarychev and Eyjafjallajökull in 2008–2010 based on CARIBIC observations

et al. 2013

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Large volcanic eruptions impact significantly on climate and lead to ozone depletion due to injection of particles and gases into the stratosphere where their residence times are long. In this the composition of volcanic aerosol is an important but inadequately studied factor. Samples of volcanically influenced aerosol were collected following the Kasatochi (Alaska), Sarychev (Russia) and also during the Eyjafjallajökull (Iceland) eruptions in the period 2008–2010. Sampling was conducted by the CARIBIC platform during regular flights at an altitude of 10–12 km as well as during dedicated flights through the volcanic clouds from the eruption of Eyjafjallajökull in spring 2010. Elemental concentrations of the collected aerosol were obtained by accelerator-based analysis. Aerosol from the Eyjafjallajökull volcanic clouds was identified by high concentrations of sulphur and elements pointing to crustal origin, and confirmed by trajectory analysis. Signatures of volcanic influence were also used to detect volcanic aerosol in stratospheric samples collected following the Sarychev and Kasatochi eruptions. In total it was possible to identify 17 relevant samples collected between 1 and more than 100 days following the eruptions studied. The volcanically influenced aerosol mainly consisted of ash, sulphate and included a carbonaceous component. Samples collected in the volcanic cloud from Eyjafjallajökull were dominated by the ash and sulphate component (&sim;45% each) while samples collected in the tropopause region and LMS mainly consisted of sulphate (50–77%) and carbon (21–43%). These fractions were increasing/decreasing with the age of the aerosol. Because of the long observation period, it was possible to analyze the evolution of the relationship between the ash and sulphate components of the volcanic aerosol. From this analysis the residence time (1/e) of sulphur dioxide in the studied volcanic cloud was estimated to be 45 ± 22 days

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confidence: 51%

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confidence: 99%

Composition and evolution of volcanic aerosol from eruptions of Kasatochi, Sarychev and Eyjafjallajökull in 2008–2010 based on CARIBIC observations

et al. 2013

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“…Occasionally chemical elements connected with crustal matter and fires are observed (Papaspiropoulos et al, 2002), which on rare occasions can have a strong influence on aerosol particle concentration (Eguchi et al, 2009;Dirksen et al, 2009;Fromm et al, 2010). Particles from explosive volcanism have strong effects on the studied region at times, affecting the climate (Ammann et al, 2003;Solomon et al, 2011), stratospheric ozone (McCormick et al, 1995) and aviation (Gislason et al, 2011). The aerosol particles in volcanic clouds contain besides the ash component (Schumann et al, 2011;Andersson et al, 2013) large sulphurous and carbonaceous components (Martinsson et al, 2009;Schmale et al, 2010;Carn et al, 2011).…”

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confidence: 99%

Comparison between CARIBIC Aerosol Samples Analysed by Accelerator-Based Methods and Optical Particle Counter Measurements

et al. 2014

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Abstract. Inter-comparison of results from two kinds of aerosol systems in the CARIBIC (Civil Aircraft for the Regular Investigation of the atmosphere Based on a Instrument Container) passenger aircraft based observatory, operating during intercontinental flights at 9-12 km altitude, is presented. Aerosol from the lowermost stratosphere (LMS), the extra-tropical upper troposphere (UT) and the tropical mid troposphere (MT) were investigated. Aerosol particle volume concentration measured with an optical particle counter (OPC) is compared with analytical results of the sum of masses of all major and several minor constituents from aerosol samples collected with an impactor. Analyses were undertaken with the following accelerator-based methods: particle-induced X-ray emission (PIXE) and particle elastic scattering analysis (PESA). Data from 48 flights during 1 year are used, leading to a total of 106 individual comparisons. The ratios of the particle volume from the OPC and the total mass from the analyses were in 84 % within a relatively narrow interval. Data points outside this interval are connected with inlet-related effects in clouds, large variability in aerosol composition, particle size distribution effects and some cases of non-ideal sampling. Overall, the comparison of these two CARIBIC measurements based on vastly different methods show good agreement, implying that the chemical and size information can be combined in studies of the MT/UT/LMS aerosol.

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“…1). Two schools of idea exist regarding what causes this hiatus of global warming: one suggests a slowdown in radiative forcing due to the stratospheric water vapour 3 , the rapid increase of stratospheric and tropospheric aerosols 4,5 , and the solar minimum around 2009 (ref. anomalies in the equatorial eastern Pacific (8.2% of the Earth surface) follow the observed evolution (see Methods).…”

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confidence: 99%

Recent global-warming hiatus tied to equatorial Pacific surface cooling

Kosaka

Xie

2013

Nature

1,502

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The Persistently Variable “Background” Stratospheric Aerosol Layer and Global Climate Change

Cited by 548 publications

References 26 publications

Composition and evolution of volcanic aerosol from eruptions of Kasatochi, Sarychev and Eyjafjallajökull in 2008–2010 based on CARIBIC observations

Composition and evolution of volcanic aerosol from eruptions of Kasatochi, Sarychev and Eyjafjallajökull in 2008–2010 based on CARIBIC observations

Comparison between CARIBIC Aerosol Samples Analysed by Accelerator-Based Methods and Optical Particle Counter Measurements

Recent global-warming hiatus tied to equatorial Pacific surface cooling

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