Phase transitions of sea‐salt/water mixtures at low temperatures: Implications for ozone chemistry in the polar marine boundary layer

Koop, Thomas; Kapilashrami, Abha; Molina, Luisa T.; Molina, Mario J.

doi:10.1029/2000jd900413

Cited by 226 publications

(348 citation statements)

References 51 publications

(26 reference statements)

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“…42,43 As shown in Movie S5 (ESI †), both NaCl deliquescence and water condensation occurred uniformly across the sample area, indicating homogeneous water vapor distribution across the 0.2 mm 2 sample area probed in the experiments presented here.…”

Section: Precise Temperature Measurementsmentioning

confidence: 89%

Direct observation of ice nucleation events on individual atmospheric particles

Wang

Knopf

China

et al. 2016

Phys. Chem. Chem. Phys.

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The work presents microscopic observations of heterogeneous ice nucleation from experiments conducted inside an environmental scanning electron microscope. Observations of ice formation on kaolinite particles demonstrate that ice preferentially nucleates at the edges of the stacked platelets, rather than on the basal planes. This platform is applied for directly detecting and tracking ice nucleating particles in ambient aerosol samples and is complemented by micro-spectroscopic chemical imaging. This technique opens a path to new physical chemistry studies of ice formation in atmospheric science, cryobiology, and material science.www.rsc.org/pccp Heterogeneous ice nucleation is a physical chemistry process of critical relevance to a range of topics in the fundamental and applied sciences and technologies. Heterogeneous ice nucleation remains insufficiently understood, partially due to the lack of experimental methods capable of obtaining in situ microscopic details of ice formation over nucleating substrates or particles. We present microscopic observations of ice nucleation events on kaolinite particles at the nanoscale and demonstrate the capability of direct tracking and micro-spectroscopic characterization of individual ice nucleating particles (INPs) in an authentic atmospheric sample. This approach utilizes a custom-built ice nucleation cell, interfaced with an Environmental Scanning Electron Microscope (IN-ESEM platform) operated at temperatures and relative humidities relevant for heterogeneous ice nucleation. The IN-ESEM platform allows dynamic observations of individual ice formation events over particles in isobaric and isothermal experiments. Isothermal experiments on individual kaolinite particles demonstrate that ice crystals preferably nucleate at the edges of the stacked kaolinite platelets, rather than on their basal planes.These experimental observations of the location of ice nucleation provide direct information for further theoretical chemistry predictions of ice formation on kaolinite.

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Section: Precise Temperature Measurementsmentioning

confidence: 89%

Direct observation of ice nucleation events on individual atmospheric particles

Wang

Knopf

China

et al. 2016

Phys. Chem. Chem. Phys.

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“…Field as well as laboratory measurements suggest that the photochemical release of Br 2 and BrCl is responsible for the destruction of the surface layer ozone in the Arctic at polar sunrise [53][54][55]. Similar bromine chemistry involving, albeit, lower mixing ratios of Br 2 and BrCl, is anticipated also in mid-latitudes [56].…”

mentioning

confidence: 85%

Ions at the Air/Water Interface

2002

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We present results from theoretical studies of aqueous ionic solvation of alkali halides aimed at developing a microscopic description of structure and dynamics at the interface between air and salt solutions. The traditional view has depicted the air/solution interface of simple electrolytes as being devoid of ions. However, it is now firmly established that polarizable anions, such as the heavier halides, occupy the surface of small to medium sized water clusters. Using a combination of theoretical calculations, including ab initio quantum chemistry, Car-Parrinello molecular dynamics simulations, and primarily molecular dynamics simulations based on polarizable force fields, we present a unified view of the interfacial structure of aqueous ionic clusters and bulk solutions. Indeed, we demonstrate that the heavier halogen anions have a propensity for the interface that is proportional to their polarizabil- * Electronic mail: jungwirt@jh-inst.cas.cz † Electronic mail: dtobias@uci.edu 2

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“…Using a typical value of RH = 80 %, a NaCl solution of m(Na + (aerosol)) ≈ 5 mol/kg is reached (Tang et al, 1997). According to Koop et al (2000), the deliquescence/efflorescence curves of sea salt hardly depend on temperature, suggesting that the water activity of sea salt solutions of fixed molality also remains nearly constant with changes in temperature. Thus, like Sander et al (2006), we assume a NaCl molality of 5 mol/kg in aerosol particles for RH = 80% at all temperatures.…”

Section: Equilibration With Ambient Humidity (Evapoconcentration)mentioning

confidence: 99%

Introducing the bromide/alkalinity ratio for a follow-up discussion on "Precipitation of salts in freezing seawater and ozone depletion events: a status report", by Morin et al., published in Atmos. Chem. Phys., 8, 7317–7324, 2008

Sander

Morin

2010

Atmos. Chem. Phys.

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Abstract. Sander et al. (2006) proposed that CaCO 3 precipitation can be an important factor in triggering tropospheric ozone depletion events. Recently, Morin et al. (2008b) presented calculations with the FREZCHEM model and concluded that their results and interpretation cast doubt on the validity of this hypothesis. In this joint publication, we have re-analyzed the implications of the FREZCHEM results and show how they can be reconciled with the proposal of Sander et al. (2006). The chemical predictions of both approaches are consistent. Although an interpretation solely based on the alkalinity change in the brine does not support the conclusion of Sander et al. (2006), we show that the bromide/alkalinity ratio (which increases during the cooling of the brine) can be used as an indicator of the potential for triggering bromine explosions.

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Phase transitions of sea‐salt/water mixtures at low temperatures: Implications for ozone chemistry in the polar marine boundary layer

Cited by 226 publications

References 51 publications

Direct observation of ice nucleation events on individual atmospheric particles

Direct observation of ice nucleation events on individual atmospheric particles

Ions at the Air/Water Interface

Introducing the bromide/alkalinity ratio for a follow-up discussion on "Precipitation of salts in freezing seawater and ozone depletion events: a status report", by Morin et al., published in Atmos. Chem. Phys., 8, 7317–7324, 2008

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Phase transitions of sea‐salt/water mixtures at low temperatures: Implications for ozone chemistry in the polar marine boundary layer

Cited by 226 publications

References 51 publications

Direct observation of ice nucleation events on individual atmospheric particles

Direct observation of ice nucleation events on individual atmospheric particles

Ions at the Air/Water Interface

Introducing the bromide/alkalinity ratio for a follow-up discussion on &quot;Precipitation of salts in freezing seawater and ozone depletion events: a status report&quot;, by Morin et al., published in Atmos. Chem. Phys., 8, 7317–7324, 2008

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Introducing the bromide/alkalinity ratio for a follow-up discussion on "Precipitation of salts in freezing seawater and ozone depletion events: a status report", by Morin et al., published in Atmos. Chem. Phys., 8, 7317–7324, 2008