Hygroscopic Growth and Deliquescence of NaCl Nanoparticles Mixed with Surfactant SDS

Harmon, Christopher W.; Grimm, Ronald L.; McIntire, Theresa M.; Peterson, Mark D.; Njegic, Bosiljka; Angel, Vanessa M.; Alshawa, Ahmad; Underwood, J. S.; Tobias, Douglas J.; Gerber, R. B.; Gordon, Mark S.; Hemminger, John C.; Nizkorodov, Sergey A.

doi:10.1021/jp909661q

Cited by 49 publications

(56 citation statements)

References 64 publications

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“…The distribution of diameters selected by the DMA is assumed to be log-normal described by a geometric mean diameter, d g , (which is also the median diameter) and a geometric standard deviation, σ g . The geometric standard deviation was taken to be σ g = 1.05, which is similar to values reported previously for this type of DMA (Hering and McMurry 1991;Spindler et al 2007;Anttila et al 2009;Harmon et al 2010). Particles with d > 600 nm were selected such that contributions by doublycharged particles transmitted by the DMA accounted for less than 1% of the measured extinction as estimated from the distribution of diameters produced by the nebulizer, the charging efficiency of the 85 Kr source and DMA transfer function.…”

Section: Aerosol Generation Size Selection and Countingmentioning

confidence: 99%

A Calibration Technique for Improving Refractive Index Retrieval from Aerosol Cavity Ring-Down Spectroscopy

Toole¹,

Renbaum-Wolff

Smith³

2013

Aerosol Science and Technology

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Cavity ring-down spectroscopy (CRDS) is a technique that is commonly used to measure the extinction of light by aerosol particles in situ. This extinction, when normalized to particle concentration, yields the extinction cross section, a measure of a single particle's ability to scatter and absorb light. The complex index of refraction can then be retrieved by comparison of the extinction cross sections at several particle diameters with those predicted by Mie theory. This approach requires accurate determination of particle diameter and concentration as well as the length of the extinction region in the cavity, but it is often difficult to quantify the systematic errors in the measurements of these quantities. Here, we introduce a calibration technique using particles of a reference compound to account for these systematic errors. The two calibration parameters are: C f , which scales the measured extinction cross sections, and d, which shifts the particle diameters. It is found that C f correlates strongly with the condensation particle counter (CPC) used to measure particle concentration and that d is associated with the differential mobility analyzer (DMA) used to select particle diameters. Calibration is shown to reduce errors of subsequently-measured extinction cross sections of a test aerosol from 11% to <2% with a concomitant improvement in the accuracy of the retrieved complex index of refraction and corresponding atmospheric radiative forcing estimates.

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Section: Aerosol Generation Size Selection and Countingmentioning

confidence: 99%

A Calibration Technique for Improving Refractive Index Retrieval from Aerosol Cavity Ring-Down Spectroscopy

Toole¹,

Renbaum-Wolff

Smith³

2013

Aerosol Science and Technology

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“…In the MD study by Harmon et al (2010), GF of between 1.6 for RH 080% up to 2.0 for RH095% are reported for sodium chloride particles. Higher GFs are expected and depends on the better ability for salt particles to absorb water molecules (hygroscopicity) than for the DFAAs.…”

Section: Solubility and Growth Factormentioning

confidence: 99%

Cloud droplet activation mechanisms of amino acid aerosol particles: insight from molecular dynamics simulations

Hede

et al. 2013

Tellus B: Chemical and Physical Meteorology

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A B S T R A C T Atmospheric amino acids constitute a large fraction of water-soluble organic nitrogen compounds in aerosol particles, and have been confirmed as effective cloud condensation nuclei (CCN) materials in laboratory experiments. We present a molecular dynamics (MD) study of six amino acids with different structures and chemical properties that are relevant to the remote marine atmospheric aerosolÁcloud system, with the aim of investigating the detailed mechanism of their induced changes in surface activity and surface tension, which are important properties for cloud drop activation. Distributions and orientations of the amino acid molecules are studied; these L-amino acids are serine (SER), glycine (GLY), alanine (ALA), valine (VAL), methionine (MET) and phenylalanine (PHE) and are categorised as hydrophilic and amphiphilic according to their affinities to water. The results suggest that the presence of surface-concentrated amphiphilic amino acid molecules give rise to enhanced LennardÁJones repulsion, which in turn results in decreased surface tension of a planar interface and an increased surface tension of the spherical interface of droplets with diameters below 10 nm. The observed surface tension perturbation for the different amino acids under study not only serves as benchmark for future studies of more complex systems, but also shows that amphiphilic amino acids are surface active. The MD simulations used in this study reproduce experimental results of surface tension measurements for planar interfaces and the method is therefore applicable for spherical interfaces of nano-size for which experimental measurements are not possible to conduct.

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“…Compared with the DRH of inorganic salts in the bulk phase, the uncoated model by Mirabel et al (2000) predicts lower DRHs, whereas the coated model by Russell and Ming (2002) predicts higher DRHs for nanoparticles (see Figure 4 in Biskos et al (2006a). The thin aqueous film formed on the particle surface alters the surface tension and surface thermodynamics at the interface, resulting in different size effects on DRH for inorganic nanoparticles (Biskos et al 2006a;Harmon et al 2010). Therefore, in studying the hygroscopic behavior of inorganic salt particles, we must investigate the formation of an aqueous film on the particle surface before DRH as well as the effects of particle size and chemical composition.…”

Section: Introductionmentioning

confidence: 99%

“…Early studies have suggested that inorganic particles would begin to be more compressed and spherical because of water adsorption on the particle surface; that is, forming an aqueous film before the DRH of the particles Romakkaniemi et al 2001;Russell and Ming 2002;Biskos et al 2006a;Wise et al 2009;Harmon et al 2010). Some researchers have experimentally observed a slight change in diameter in the inorganic salt particles of NaCl and (NH 4 ) 2 SO 4 below DRH by using Fourier-transform infrared spectroscopy (Dai et al 1995), an environmental transmission electron microscope (Wise et al 2005), environmental atomic force microscopy (Bruzewicz et al 2011), and hygroscopic tandem differential mobility analyzer (H-TDMA) systems with a nano-DMA (Ghosal and Hemminger 1999;Romakkaniemi et al 2001;Biskos et al 2006a).…”

Section: Introductionmentioning

confidence: 99%

Aqueous film formation on irregularly shaped inorganic nanoparticles before deliquescence, as revealed by a hygroscopic differential mobility analyzer–Aerosol particle mass system

Hsiao

Young

Tai

et al. 2016

Aerosol Science and Technology

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A hygroscopic tandem differential mobility analyzer (H-TDMA) and a hygroscopic coupled DMA and aerosol particle mass (H-DMA-APM) were coupled to examine aqueous film formation and the deliquescence behavior of inorganic nanoparticles. The two systems complement each other because H-DMA-APM measures mass change, while H-TDMA measures mobility diameter (volume) change of nanoparticles upon water uptake. The former mass change was, in particular, more capable to discern minute particle phase changes than the latter size change at moderate RHs. The mass and diameter changes were used to derive the particle effective density for evaluation of aqueous film formation on the nanoparticle surface before and after deliquescence transition. The measurements further showed that approximately 3-5 and 12-20 monolayer equivalents of water molecules formed on the respective surface of 50-and 100-nm inorganic aerosols (ammonium sulfate and sodium chloride) before deliquescence relative humidity (DRH). These findings support the physical basis of the coated-surface model given by Russell and Ming in 2002, and suggest that the phase transition of inorganic nanoparticles near deliquescence is a gradual process instead of an abrupt change. This phenomenon changed the surface energy values, thus confirming the explanation that the DRH of nanoparticles increases as the particle size decreases. This is the first direct observation of nanoparticle deliquescence phase transition using the H-DMA-APM system, and the detailed characterization of aqueous film formation on inorganic nanoparticles is feasible with the presented measurement systems.

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Hygroscopic Growth and Deliquescence of NaCl Nanoparticles Mixed with Surfactant SDS

Cited by 49 publications

References 64 publications

A Calibration Technique for Improving Refractive Index Retrieval from Aerosol Cavity Ring-Down Spectroscopy

A Calibration Technique for Improving Refractive Index Retrieval from Aerosol Cavity Ring-Down Spectroscopy

Cloud droplet activation mechanisms of amino acid aerosol particles: insight from molecular dynamics simulations

Aqueous film formation on irregularly shaped inorganic nanoparticles before deliquescence, as revealed by a hygroscopic differential mobility analyzer–Aerosol particle mass system

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