The Effects of Organic Species on the Hygroscopic Behaviors of Inorganic Aerosols

Choi, Man Yee; Chan, Chak K.

doi:10.1021/es0113293

Cited by 337 publications

(476 citation statements)

References 45 publications

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“…12,32 Measured GF values for the mixed particles were approximately consistent with the assumption that the organic and inorganic species adsorb water independently, in accordance with the ZdanovskiiStokes-Robinson (ZSR) model. 33,34 Similar conclusions were reached in studies of water activities above the bulk mixtures of the same compounds. 35,36 The main objective of this work is to test the effect of sparingly soluble organic coatings on hygroscopic properties of NaCl nanoparticles.…”

Section: Introductionsupporting

confidence: 71%

Hygroscopic Growth and Deliquescence of NaCl Nanoparticles Coated with Surfactant AOT

et al. 2009

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Aerosolized nanoparticles of NaCl coated with variable amounts of surfactant AOT were generated by electrospraying AOT/NaCl aqueous solutions, followed by neutralizing and drying the resulting particles. A tandem differential mobility analyzer was used to select a narrow size distribution of particles with mobility equivalent diameters below 20 nm and monitor their hygroscopic growth as a function of relative humidity. Effects of the particle size and relative amount of surfactant on the hygroscopic growth of NaCl were studied. For pure NaCl nanoparticles, the deliquescence relative humidity (DRH) increased as the particle size was decreased, in full agreement with previous measurements. Below the DRH the NaCl nanoparticles had an equivalent of one-four monolayers of water adsorbed on the surface. The addition of a sub-monolayer AOT coating reduced the DRH and suppressed the hygroscopic growth of the NaCl core. At AOT coverage levels exceeding one monolayer, a clear deliquescence transition was no longer discernible. The Zdanovskii-StokesRobinson (ZSR) model failed to predict the observed growth factors of mixed AOT/NaCl nanoparticles reflecting a large contribution of the interfacial interactions between NaCl and AOT to the total free energy of the particles. There were indications that AOT/NaCl nanoparticles prepared by the electrospray aerosol source were enhanced in the relative mass fraction of AOT in comparison with the solution from which they were electrosprayed.

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Section: Introductionsupporting

confidence: 71%

Hygroscopic Growth and Deliquescence of NaCl Nanoparticles Coated with Surfactant AOT

et al. 2009

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“…Variation in the water content of the AS-MA particles in the course of a humidity cycle is shown in Figure 3 along with data from previous measurements using the EDB techniques (Choi and Chan 2002;Ling and Chan 2008). The AS-MA particles in this study are of the same composition (1:1 mole ratio) with those studied in the literature.…”

Section: Hygroscopicitysupporting

confidence: 54%

Water Content and Phase Transitions in Particles of Inorganic and Organic Species and their Mixtures Using Micro-Raman Spectroscopy

Yeung

Chan

2010

Aerosol Science and Technology

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Hygroscopicity and phase transitions were measured with deposited particles of ammonium sulfate (AS), ammonium nitrate (AN), malonic acid (MA), glutaric acid (GA), glyoxylic acid (GlyA), as well as two mixed particle systems AS-MA and AS-GA using micro-Raman spectroscopy. Hygroscopicity was presented in terms of water-to-solute mass ratios, which were obtained from the integrated area ratios of the Raman water band to a distinct solute peak. Deliquescence and crystallization were confirmed by abrupt changes in the Raman peak positions and the full-widthhalf-heights of distinct solute peaks. The results for AS, AN, MA, and GA agreed well with literature reports and model predictions. For GlyA, we detected the Raman water band at near 0% RH, indicating that the spectral technique is sensitive for hygroscopic measurements at very low RH. Additional spectral feature at ∼0% RH was also observed. In the case of more complicated ASdicarboxylic acid mixed systems, the partial phase transitions of the organic components were identified using the intensity ratios of aqueous to solid C=O peaks. AS-MA particles did not completely crystallize and gradual water uptake with increasing RH from 3% was observed. Moreover, it was found that AS-GA particles showed step-wise crystallization in which the AS fraction crystallized prior to the GA fraction. The measured water content and complete DRH of both mixed systems were consistent with the published values. The results show the utility of micro-Raman spectroscopic analysis in studying hygroscopicity and phase characterizations of the chemical species in mixed particles.

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“…In this work, the particle deliquesced completely at 74-75% RH when the normalized FWHM of the AS peak surged, consistent with the predictions. The full DRH of the 30 wt% MA particle was lower than the respective pure AS (80% RH) and MA (86% RH) values (Peng et al 2001;Choi and Chan 2002), owing to the entropy enhancement during solvation/mixing (Marcolli et al 2004). The DRH reduction of mixed particles has been reported earlier even for sparingly soluble organic/inorganic mixtures, such as the mixture of adipic acid and AS (Yeung et al 2009).…”

Section: Changes In Hygroscopicity Of Aqueous and Solid Particles Aftmentioning

confidence: 70%

“…Some highly aged organic aerosols may have oxygen-to-carbon ratio as high as unity (Aiken et al 2008). The oxidative transformation results in changing aerosol loadings and physicochemical properties, such as the hygroscopicity (Choi and Chan 2002;Yeung et al 2009), the cloud condensation nuclei (CCN) activity (Shilling et al 2007), and the optical properties (Shapiro et al 2009), which in turn complicate the highly uncertain radiative forcing of aerosols (Heald et al 2005). It is important to understand how these heterogeneous aging processes affect the transformation of organic aerosols.…”

Section: Introductionmentioning

confidence: 99%

Roles of the Phase State and Water Content in Ozonolysis of Internal Mixtures of Maleic Acid and Ammonium Sulfate Particles

Chan

2012

Aerosol Science and Technology

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The ozonolysis of maleic acid/ammonium sulfate (MA/AS, 30/70 wt%) internal mixtures was investigated at various relative humidities (RHs) (80%, 55%, 30%, and <5%) and physical states (aqueous and crystalline solid). Complementary laboratory techniques-an electrodynamic balance coupled with in situ Raman spectroscopy and a reaction flow cell coupled with offline ion chromatography (IC)-were employed to probe the mass changes, spectroscopic changes, product identities, and post-reaction hygroscopic changes in ozone-processed MA/AS mixed particles. The rate of ozonolysis was highly dependent on the physical state and the water content of the particles. Crystalline solid particles underwent negligible changes even after exposure to 10-ppm ozone for six days. Aqueous particles reacted much faster and the rate was related to the RH during reaction. It took 23 h to reduce MA to 50% of its initial mass at 80% RH, whereas it took 87 h to do the same at 55% RH or lower. We believe that the salting-out of ozone in concentrated droplets at 55% RH may have contributed to the reduced ozonolysis rate. The molar conversion of MA to glyoxylic acid was about unity in both the 55% RH and the 80% RH experiments. Exposed particles may have formed amorphous solids when dried and their hygroscopicity was different from that of the corresponding parent particles. Early deliquescence of reacted particles was observed, suggesting the strong influence of aging on aerosol hygroscopicity.

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The Effects of Organic Species on the Hygroscopic Behaviors of Inorganic Aerosols

Cited by 337 publications

References 45 publications

Hygroscopic Growth and Deliquescence of NaCl Nanoparticles Coated with Surfactant AOT

Hygroscopic Growth and Deliquescence of NaCl Nanoparticles Coated with Surfactant AOT

Water Content and Phase Transitions in Particles of Inorganic and Organic Species and their Mixtures Using Micro-Raman Spectroscopy

Roles of the Phase State and Water Content in Ozonolysis of Internal Mixtures of Maleic Acid and Ammonium Sulfate Particles

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