Ice nucleation activity of silicates and aluminosilicates in pure water and aqueous solutions – Part 3: Aluminosilicates

Kumar, Anand; Marcolli, Claudia; Peter, Thomas

doi:10.5194/acp-19-6059-2019

Cited by 57 publications

(105 citation statements)

References 161 publications

(257 reference statements)

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“…Arid and semiarid regions are the main sources of mineral dust (e.g., Saharan and Gobi deserts) (Laurent et al, 2006(Laurent et al, , 2008, which can have atmospheric lifetimes of several days (Huneeus et al, 2011). The dust, while being transported, can interact with a variety of trace gases (Usher et al, 2003;Kolb et al, 2010), which can lead to changes in the surface physicochemical properties.…”

Section: Atmospheric Implicationsmentioning

confidence: 99%

Ice nucleation activity of silicates and aluminosilicates in pure water and aqueous solutions – Part 2: Quartz and amorphous silica

2019

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Abstract. Divergent ice nucleation (IN) efficiencies of quartz, an important component of atmospheric mineral dust, have been reported in previous studies. We show here that quartz particles obtain their IN activity from milling and that quartz aged in water loses most of its IN efficiency relative to freshly milled quartz. Since most studies so far reported IN activities of commercial quartz dusts that were milled already by the manufacturer, IN active samples prevailed. Also, the quartz surface – much in contrast to that of feldspars – is not prone to ammonia-induced IN enhancement. In detail we investigate the influence of solutes on the IN efficiency of various silica (SiO2) particles (crystalline and amorphous) with special focus on quartz. We performed immersion freezing experiments and relate the observed variability in IN activity to the influence of milling, the aging time and to the exposure conditions since milling. Immersion freezing with silica particles suspended in pure water or aqueous solutions of NH3, (NH4)2SO4, NH4HSO4, Na2SO4 and NaOH, with solute concentrations corresponding to water activities aw=0.9–1.0, were investigated in emulsified droplets by means of differential scanning calorimetry (DSC) and analyzed in terms of the onset temperature of the heterogeneous freezing signal Thet and the heterogeneously frozen water volume fraction Fhet. Quartz particles, which originate from milling coarse samples, show a strong heterogeneous freezing peak in pure water with Thet equal to 247–251 K. This IN activity disappears almost completely after aging for 7 months in pure water in a glass vial. During this time quartz slowly grew by incorporating silicic acid leached from the glass vial. Conversely, the synthesized amorphous silica samples show no discernable heterogeneous freezing signal unless they were milled. This implies that defects provide IN activity to silica surfaces, whereas the IN activity of a natural quartz surface is negligible, when it grew under near-equilibrium conditions. For suspensions containing milled quartz and the solutes (NH4)2SO4, NH4HSO4 or Na2SO4, Thet approximately follows ThetΔawhet(aw), the heterogeneous freezing onset temperatures that obey Δawhet criterion, i.e., ThetΔawhet(aw)=Tmelt(aw+Δawhet) with Δawhet being a constant offset with respect to the ice melting point curve, similar to homogeneous IN. This water-activity-based description is expected to hold when the mineral surface is not altered by the presence of the solutes. On the other hand, we observe a slight enhancement in Fhet in the presence of these solutes, implying that the compliance with the Δawhet criterion does not necessarily imply constant Fhet. In contrast to the sulfates, dilute solutions of NH3 or NaOH (molality ≥5×10-4 mol kg−1) reveal Thet by 3–8 K lower than ThetΔawhet(aw), indicating a significant impact on the mineral surface. The lowering of Thet of quartz suspended in dilute NH3 solutions is opposite to the distinct increase in Thet that we found in emulsion freezing experiments with aluminosilicates, namely feldspars, kaolinite, gibbsite and micas. We ascribe this decrease in IN activity to the increased dissolution of quartz under alkaline conditions. The defects that constitute the active sites appear to be more susceptible to dissolution and therefore disappear first on a dissolving surface.

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Section: Atmospheric Implicationsmentioning

confidence: 99%

Ice nucleation activity of silicates and aluminosilicates in pure water and aqueous solutions – Part 2: Quartz and amorphous silica

2019

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“…Our measurements were collected within a few hours of dust addition, but longer ocean residence times could potentially alter the structure and/or composition of the dust through dissolution and/or disrupting active sites, though Perkins et al (2020) found that incubation in sea salt had little effect upon the IN‐activity of ATD once colligative effects had been considered. However, feldspar is a major contributor to mineral dust INPs, and their ice nucleation activity can be reduced by the presence of aqueous salt (Kumar et al, 2019; Whale et al, 2018), and thus, more investigation is needed to understand the effects of suspension in seawater on the IN‐activity of mineral dust. Seawater also contains small (<0.2 μm) organic ice nucleating entities (INE) from diatom or bacterial exudates that freeze at temperatures ≥ −8°C (McCluskey, Hill, Humphries, et al, 2018; Wilson et al, 2015).…”

Section: Resultsmentioning

confidence: 99%

Ejection of Dust From the Ocean as a Potential Source of Marine Ice Nucleating Particles

et al. 2020

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Oceans are, generally, relatively weak sources of ice nucleating particles (INPs). Thus, dust transported from terrestrial regions can dominate atmospheric INP concentrations even in remote marine regions. Studies of ocean-emitted INPs have focused upon sea spray aerosols containing biogenic species. Even though large concentrations of dust are transported over marine regions, resuspended dust has never been explicitly considered as another possible source of ocean-emitted INPs. Current models assume that deposited dust is not re-emitted from surface waters. Our laboratory studies of aerosol particles produced from coastal seawater and synthetic seawater doped with dust show that dust can indeed be ejected from water during bubble bursting. INP concentration measurements show these ejected dust particles retain ice nucleating activity. Doping synthetic seawater to simulate a strong dust deposition event produced INPs active at temperatures colder than −13°C and INP concentrations 1 to 2 orders of magnitude greater than either lab sea spray or marine boundary layer measurements. The relevance of these laboratory findings is highlighted by single-particle composition measurements along the Californian coast where at least 9% of dust particles were mixed with sea salt. Additionally, global modeling studies show that resuspension of dust from the ocean could exert the most impact over the Southern Ocean, where ocean-emitted INPs are thought to dominate atmospheric INP populations. More work characterizing the factors governing the resuspension of dust particles is required to understand the potential impact upon clouds. Plain Language Summary Clouds are formed through the deposition of water onto aerosol particles. A rare subset of these aerosol particles, ice nucleating particles (INPs), is required for cloud droplets to freeze at temperatures warmer than −38°C and can profoundly affect climate. Unfortunately, the identity and sources of INPs in marine regions are not well understood. Dust particles from land masses can be transported over marine regions where they commonly deposit to the ocean's surface in what has been assumed to be a one-way atmospheric loss process. We show through a combination of lab, field, and modeling studies that dust can be re-ejected in sea spray aerosols and still act as INPs. Modeling studies indicate that oceanic dust INPs will have the greatest influence over the Southern Ocean.

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“…Lithium iodide was found to increase the freezing temperature of kaolinite particles in one study (Reischel and Vali, 1975), but not in a more recent study (Ren et al, 2020). Other inorganic salts including, NaOH and NaCl, decrease the freezing temperatures of some types mineral dusts (Kumar et al, 2019a(Kumar et al, , 2018(Kumar et al, , 2019bReischel and Vali, 1975;Whale et al, 2015). Inorganic acids either decrease the ice nucleation ability of mineral dust particles or have little effect, depending on the type of acid, exposure time, concentration of the acid, and type of mineral dust (Kumar et al, 2018;Burkert-Kohn et al, 2017;Sullivan et al, 2010b;Tobo et al, 2012;Augustin-Bauditz et al, 2014;Wex et al, 2014;Sullivan et al, 2010a;Link et al, 2020).…”

Section: Introductionmentioning

confidence: 89%

“…For comparison purposes, we also investigated the effect of (NH4)2SO4 on the ice nucleating ability of four types of mineral dust (Arizona Test Dust, K-rich feldspar, montmorillonite, and kaolinite). The effect of (NH4)2SO4 on the ice nucleating ability of Arizona Test Dust, K-rich feldspar, and kaolinite, has been studied before (Kumar et al, 2018;Whale et al, 2018;Kumar et al, 2019b), but the effect on montmorillonite has not.…”

Section: Ins Suspensionsmentioning

confidence: 99%

The effect of (NH4)2SO4 on the freezing properties of non-mineral dust ice nucleating substances of atmospheric relevance

Worthy

Kumar

et al. 2021

Preprint

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Abstract. A wide range of materials including mineral dust, soil dust, and bioaerosols have been shown to act as ice nuclei in the atmosphere. During atmospheric transport, these materials can become coated with inorganic and organic solutes which may impact their ability to nucleate ice. While a number of studies have investigated the impact of solutes at low concentrations on ice nucleation by mineral dusts, very few studies have examined their impact on non-mineral dust ice nuclei. We studied the effect of dilute (NH4)2SO4 solutions on immersion freezing of a variety of non-mineral dust ice nucleating substances including bacteria, fungi, sea ice diatom exudates, sea surface microlayer, and humic substances using the droplet freezing technique. We also studied the effect of (NH4)2SO4 on immersion freezing of mineral dust particles for comparison purposes. (NH4)2SO4 had no effect on the median freezing temperature of nine of the ten tested non-mineral dust materials. There was a small but statistically significant decrease in the median freezing temperature of the bacteria X. campestris (change in median freezing temperature ∆T_50 = -0.43 ± 0.19 °C) in the presence of (NH4)2SO4 compared to pure water. Conversely, (NH4)2SO4 increased the median freezing temperature of four different mineral dusts (Potassium-rich feldspar, Arizona Test Dust, Kaolinite, Montmorillonite) by 3 °C to 8 °C. This significant difference in the response of mineral dust and non-mineral dust ice nucleating substances when exposed to (NH4)2SO4 suggests that they nucleate ice and/or interact with (NH4)2SO4 via different mechanisms. This difference suggests that the relative importance of mineral dust to non-mineral dust particles for ice nucleation in mixed-phase clouds could increase as these particles become coated with ammonium sulfate in the atmosphere. This difference also suggests that the addition of (NH4)2SO4 to atmospheric samples of unknown composition could be used as an indicator or assay for the presence of mineral dust ice nuclei.

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Ice nucleation activity of silicates and aluminosilicates in pure water and aqueous solutions – Part 3: Aluminosilicates

Cited by 57 publications

References 161 publications

Ice nucleation activity of silicates and aluminosilicates in pure water and aqueous solutions – Part 2: Quartz and amorphous silica

Ice nucleation activity of silicates and aluminosilicates in pure water and aqueous solutions – Part 2: Quartz and amorphous silica

Ejection of Dust From the Ocean as a Potential Source of Marine Ice Nucleating Particles

The effect of (NH<sub>4</sub>)<sub>2</sub>SO<sub>4</sub> on the freezing properties of non-mineral dust ice nucleating substances of atmospheric relevance

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Ice nucleation activity of silicates and aluminosilicates in pure water and aqueous solutions – Part 3: Aluminosilicates

Cited by 57 publications

References 161 publications

Ice nucleation activity of silicates and aluminosilicates in pure water and aqueous solutions – Part 2: Quartz and amorphous silica

Ice nucleation activity of silicates and aluminosilicates in pure water and aqueous solutions – Part 2: Quartz and amorphous silica

Ejection of Dust From the Ocean as a Potential Source of Marine Ice Nucleating Particles

The effect of (NH&lt;sub&gt;4&lt;/sub&gt;)&lt;sub&gt;2&lt;/sub&gt;SO&lt;sub&gt;4&lt;/sub&gt; on the freezing properties of non-mineral dust ice nucleating substances of atmospheric relevance

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The effect of (NH<sub>4</sub>)<sub>2</sub>SO<sub>4</sub> on the freezing properties of non-mineral dust ice nucleating substances of atmospheric relevance