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W2340885725 endingPage "2392" @default.
W2340885725 startingPage "2373" @default.
W2340885725 abstract "Abstract. Smoke aerosols prevail throughout Amazonia because of widespread biomass burning during the dry season, and external mixing, low variability in the particle size distribution and low particle hygroscopicity are typical. There can be profound effects on cloud properties. This study uses an adiabatic cloud model to simulate the activation of smoke particles as cloud condensation nuclei (CCN) for three hypothetical case studies, chosen as to resemble biomass burning aerosol observations in Amazonia. The relative importance of variability in hygroscopicity, mixing state, and activation kinetics for the activated fraction and maximum supersaturation is assessed. For a population with κp = 0.04, an overestimation of the cloud droplet number concentration Nd for the three selected case studies between 22.4 ± 1.4 and 54.3 ± 3.7 % was obtained when assuming a hygroscopicity parameter κp = 0.20. Assuming internal mixing of the aerosol population led to overestimations of up to 20 % of Nd when a group of particles with medium hygroscopicity was present in the externally mixed population cases. However, the overestimations were below 10 % for external mixtures between very low and low-hygroscopicity particles, as seems to be the case for Amazon smoke particles. Kinetic limitations were significant for medium- and high-hygroscopicity particles, and much lower for very low and low-hygroscopicity particles. When particles were assumed to be at equilibrium and to respond instantly to changes in the air parcel supersaturation, the overestimation of the droplet concentration was up to ∼ 100 % in internally mixed populations, and up to ∼ 250 % in externally mixed ones, being larger for the higher values of hygroscopicity. In addition, a perceptible delay between the times when maximum supersaturation and maximum aerosol activated fraction are reached was noticed and, for aerosol populations with effective hygroscopicity κpeff higher than a certain threshold value, the delay in particle activation was such that no particles were activated at the time of maximum supersaturation. Considering internally mixed populations, for an updraft velocity W = 0.5 m s−1 this threshold of no activation varied between κpeff = 0.35 and κpeff = 0.5 for the different case studies. However, for low hygroscopicity, kinetic limitations played a weaker role for CCN activation of particles, even when taking into account the large aerosol mass and number concentrations. For the very low range of hygroscopicities, the overestimation of the droplet concentration due to the equilibrium assumption was lowest and the delay between the times when maximum supersaturation and maximum activated fraction were reached was greatly reduced or no longer observed (depending on the case study). These findings on uncertainties and sensitivities provide guidance on appropriate simplifications that can be used for modeling of smoke aerosols within general circulation models. The use of medium values of hygroscopicity representative of smoke aerosols for other biomass burning regions on Earth can lead to significant errors compared to the use of low hygroscopicity for Amazonia (between 0.05 and 0.13, according to available observations). Also in this region, consideration of the biomass burning population as internally mixed will lead to small errors in the droplet concentration, while significantly increasing the computational burden. Regardless of the large smoke aerosol loads in the region during the dry season, kinetic limitations are expected to be low." @default.
W2340885725 created "2016-06-24" @default.
W2340885725 creator A5022535003 @default.
W2340885725 creator A5060850034 @default.
W2340885725 creator A5061583871 @default.
W2340885725 creator A5070196058 @default.
W2340885725 creator A5075520908 @default.
W2340885725 date "2017-02-15" @default.
W2340885725 modified "2023-10-01" @default.
W2340885725 title "Impact of mixing state and hygroscopicity on CCN activity of biomass burning aerosol in Amazonia" @default.
W2340885725 cites W109106006 @default.
W2340885725 cites W1486724394 @default.
W2340885725 cites W1508495092 @default.
W2340885725 cites W1949079599 @default.
W2340885725 cites W1969956273 @default.
W2340885725 cites W1977945389 @default.
W2340885725 cites W1980210723 @default.
W2340885725 cites W1983905340 @default.
W2340885725 cites W1985155924 @default.
W2340885725 cites W1999074307 @default.
W2340885725 cites W2002718971 @default.
W2340885725 cites W2003678836 @default.
W2340885725 cites W2004811960 @default.
W2340885725 cites W2009218236 @default.
W2340885725 cites W2017714731 @default.
W2340885725 cites W2021366996 @default.
W2340885725 cites W2024612183 @default.
W2340885725 cites W2025194650 @default.
W2340885725 cites W2025356510 @default.
W2340885725 cites W2027689587 @default.
W2340885725 cites W2046752734 @default.
W2340885725 cites W2047688540 @default.
W2340885725 cites W2050571871 @default.
W2340885725 cites W2066605780 @default.
W2340885725 cites W2067296302 @default.
W2340885725 cites W2070408950 @default.
W2340885725 cites W2073115945 @default.
W2340885725 cites W2073340285 @default.
W2340885725 cites W2082562995 @default.
W2340885725 cites W2096462582 @default.
W2340885725 cites W2099636727 @default.
W2340885725 cites W2102753760 @default.
W2340885725 cites W2103336769 @default.
W2340885725 cites W2105746136 @default.
W2340885725 cites W2106963750 @default.
W2340885725 cites W2110942699 @default.
W2340885725 cites W2112308202 @default.
W2340885725 cites W2113673259 @default.
W2340885725 cites W2113925232 @default.
W2340885725 cites W2116713346 @default.
W2340885725 cites W2118295252 @default.
W2340885725 cites W2119744638 @default.
W2340885725 cites W2119793656 @default.
W2340885725 cites W2121104231 @default.
W2340885725 cites W2125497734 @default.
W2340885725 cites W2130128720 @default.
W2340885725 cites W2131283510 @default.
W2340885725 cites W2133942622 @default.
W2340885725 cites W2134927874 @default.
W2340885725 cites W2136804601 @default.
W2340885725 cites W2137193147 @default.
W2340885725 cites W2139493086 @default.
W2340885725 cites W2143134463 @default.
W2340885725 cites W2143923537 @default.
W2340885725 cites W2144348006 @default.
W2340885725 cites W2145355715 @default.
W2340885725 cites W2151449194 @default.
W2340885725 cites W2153563413 @default.
W2340885725 cites W2161483891 @default.
W2340885725 cites W2161857435 @default.
W2340885725 cites W2162285843 @default.
W2340885725 cites W2163667214 @default.
W2340885725 cites W2164216367 @default.
W2340885725 cites W2164927380 @default.
W2340885725 cites W2169249461 @default.
W2340885725 cites W2180632338 @default.
W2340885725 cites W2325311049 @default.
W2340885725 cites W2335476165 @default.
W2340885725 cites W2616727916 @default.
W2340885725 cites W4234548773 @default.
W2340885725 doi "https://doi.org/10.5194/acp-17-2373-2017" @default.
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