Bengt G. Martinsson scite author profile

Satellite observations have shown that the Asian Summer Monsoon strongly influences the upper troposphere and lower stratosphere (UTLS) aerosol morphology through its role in the formation of the Asian Tropopause Aerosol Layer (ATAL). Stratospheric Aerosol and Gas Experiment II solar occultation and Cloud-Aerosol Lidar and Infrared Pathfinder Satellite Observation (CALIPSO) lidar observations show that summertime UTLS Aerosol Optical Depth (AOD) between 13 and 18 km over Asia has increased by three times since the late 1990s. Here we present the first in situ balloon measurements of aerosol backscatter in the UTLS from Western China, which confirm high aerosol levels observed by CALIPSO since 2006. Aircraft in situ measurements suggest that aerosols at lower altitudes of the ATAL are largely composed of carbonaceous and sulfate materials (carbon/sulfur elemental ratio ranging from 2 to 10). Back trajectory analysis from Cloud-Aerosol Lidar with Orthogonal Polarization observations indicates that deep convection over the Indian subcontinent supplies the ATAL through the transport of pollution into the UTLS. Time series of deep convection occurrence, carbon monoxide, aerosol, temperature, and relative humidity suggest that secondary aerosol formation and growth in a cold, moist convective environment could play an important role in the formation of ATAL. Finally, radiative calculations show that the ATAL layer has exerted a short-term regional forcing at the top of the atmosphere of −0.1 W/m2 in the past 18 years.Key PointsIncrease of summertime upper tropospheric aerosol levels over Asia since the 1990s Upper tropospheric enhancement also observed by in situ backscatter measurements Significant regional radiative forcing of −0.1 W/m2

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Civil Aircraft for the regular investigation of the atmosphere based on an instrumented container: The new CARIBIC system

Brenninkmeijer¹,

Crutzen²,

et al. 2007

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Hygroscopic properties of aerosol particles in the north-eastern Atlantic during ACE-2

Swietlicki¹,

Zhou²,

Covert³

et al. 2000

Tellus B

141

149

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Measurements of the hygroscopic properties of sub‐micrometer atmospheric aerosol particles were performed with hygroscopic tandem differential mobility analysers (H‐TDMA) at 5 sites in the subtropical north‐eastern Atlantic during the second Aerosol Characterization Experiment (ACE‐2) from 16 June to 25 July 1997. Four of the sites were in the marine boundary layer and one was, at least occasionally, in the lower free troposphere. The hygroscopic diameter growth factors of individual aerosol particles in the dry particle diameter range 10–440 nm were generally measured for changes in relative humidity (RH) from <10% to 90%. In the marine boundary layer, growth factors at 90% RH were dependent on location, air mass type and particle size. The data was dominated by a unimodal growth distribution of more‐hygroscopic particles, although a bimodal growth distribution including less‐hygroscopic particles was observed at times, most often in the more polluted air masses. In clean marine air masses the more‐hygroscopic growth factors ranged from about 1.6 to 1.8 with a consistent increase in growth factor with increasing particle size. There was also a tendency toward higher growth factors as sodium to sulphate molar ratio increased with increasing sea‐salt contribution at higher wind speeds. During outbreaks of European pollution in the ACE‐2 region, the growth factors of the largest particles were reduced, but only slightly. Growth factors at all sizes in both clean and polluted air masses were markedly lower at the Sagres, Portugal site due to more proximate continental influences. The frequency of occurrence of less‐hygroscopic particles with a growth factor of ca. 1.15 was greatest during polluted conditions at Sagres. The free tropospheric 50 nm particles were predominately less‐hygroscopic, with an intermediate growth factor of 1.4, but more‐hygroscopic particles with growth factors of about 1.6 were also frequent. While these particles probably originate from within the marine boundary layer, the less‐hygroscopic particles are probably more characteristic of lower free tropospheric air masses. For those occasions when measurements were made at 90% and an intermediate 60% or 70% RH, the growth factor G(RH) of the more‐hygroscopic particles could be modelled empirically by a power law expression. For the ubiquitous more‐hygroscopic particles, the expressions G(RH)=(1−RH/100)−0.210 for 50 nm Aitken mode particles and G(RH)=(1−RH/100)−0.233 for 166 nm accumulation mode particles are recommended for clean marine air masses in the north‐eastern Atlantic within the range 0

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A closure study of sub-micrometer aerosol particle hygroscopic behaviour

Swietlicki

Zhou

Berg

et al. 1999

Atmospheric Research

178

148

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Significant radiative impact of volcanic aerosol in the lowermost stratosphere

et al. 2015

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Despite their potential to slow global warming, until recently, the radiative forcing associated with volcanic aerosols in the lowermost stratosphere (LMS) had not been considered. Here we study volcanic aerosol changes in the stratosphere using lidar measurements from the NASA CALIPSO satellite and aircraft measurements from the IAGOS-CARIBIC observatory. Between 2008 and 2012 volcanism frequently affected the Northern Hemisphere stratosphere aerosol loadings, whereas the Southern Hemisphere generally had loadings close to background conditions. We show that half of the global stratospheric aerosol optical depth following the Kasatochi, Sarychev and Nabro eruptions is attributable to LMS aerosol. On average, 30% of the global stratospheric aerosol optical depth originated in the LMS during the period 2008–2011. On the basis of the two independent, high-resolution measurement methods, we show that the LMS makes an important contribution to the overall volcanic forcing.

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