Ice nucleation by fertile soil dusts: relative importance of mineral and biogenic components

O’Sullivan, Daniel; Murray, Benjamin J.; Malkin, T. L.; Whale, Thomas F.; Umo, Nsikanabasi Silas; Atkinson, James; Price, H. C.; Baustian, K. J.; Browse, Jo; Webb, Michael E.

doi:10.5194/acp-14-1853-2014

Cited by 218 publications

(293 citation statements)

References 93 publications

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“…4a, b; some of the elements found in smaller amounts: O, F, Na, Cl and K). It has long been known that SOM serves as a reservoir of nutrients, such as N, P and S (Paul, 2007). As for the samples analyzed here, all the particles categorized as organ- (e) Soot-like particle.…”

Section: Identification Of Particle Typesmentioning

confidence: 99%

“…This may suggest that there was no measurable contribution of microorganisms (e.g., bacteria and fungal spores) to the numbers of the agricultural soil dusts or IN examined here, although the possibility of the presence of some P-free microorganisms or plants (or their fragments) cannot be ruled out. Organic matter in soils is composed of a variety of macromolecules, such as lignin, cellulose, hemicellulose, protein, lipids, humic-like substances (e.g., humic acid and fulvic acid) and so on (Paul, 2007). So far, freezing experiments with certain standard humic-like substances have indicated that while they can act as IN under mixed-phase cloud conditions (Fornea et al, 2009;Wang and Knopf, 2011;Knopf and Alpert, 2013;Rigg et al, 2013;O'Sullivan et al, 2014), they are much less effective as IN than fertile soil dusts (O 'Sullivan et al, 2014).…”

Section: Identification Of Particle Typesmentioning

confidence: 99%

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Organic matter matters for ice nuclei of agricultural soil origin

et al. 2014

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Abstract. Heterogeneous ice nucleation is a crucial process for forming ice-containing clouds and subsequent iceinduced precipitation. The importance for ice nucleation by airborne desert soil dusts composed predominantly of minerals is widely acknowledged. However, the potential influence of agricultural soil dusts on ice nucleation has been poorly recognized, despite recent estimates that they may account for up to 20-25 % of the global atmospheric dust load. We have conducted freezing experiments with various dusts, including agricultural soil dusts derived from the largest dustsource region in North America. Here we show evidence for the significant role of soil organic matter (SOM) in particles acting as ice nuclei (IN) under mixed-phase cloud conditions. We find that the ice-nucleating ability of the agricultural soil dusts is similar to that of desert soil dusts, but is clearly reduced after either H 2 O 2 digestion or dry heating to 300 • C. In addition, based on chemical composition analysis, we demonstrate that organic-rich particles are more important than mineral particles for the ice-nucleating ability of the agricultural soil dusts at temperatures warmer than about −36 • C. Finally, we suggest that such organic-rich particles of agricultural origin (namely, SOM particles) may contribute significantly to the ubiquity of organic-rich IN in the global atmosphere.

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Section: Identification Of Particle Typesmentioning

confidence: 99%

Section: Identification Of Particle Typesmentioning

confidence: 99%

Organic matter matters for ice nuclei of agricultural soil origin

et al. 2014

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“…However, estimates regarding the contribution of agricultural areas to the global dust burden are not very well confined and range from less than 10% [Tegen et al, 2004] to 20-50% [Funk and Reuter, 2006;Forster et al, 2007;Ginoux et al, 2012]. Nevertheless, due to the high mass fraction of presumably ice-active biological material accompanying agricultural soil dusts, even a minor contribution of soil dust sources to the total atmospheric dust burden may have a significant impact on the abundance of atmospheric particles nucleating ice in mixed-phase clouds [Conen et al, 2011;O'Sullivan et al, 2014]. In addition, atmospherically transported agricultural soil dust particles carry not only primary biological particles but also organic matter (OM) in various forms, such as free organic matter (e.g., leaf debris), organo-mineral complexes, and secondary organic compounds [Ellerbrock et al, 2005;Kögel-Knabner et al, 2008;Conen et al, 2011;O'Sullivan et al, 2014;Conen et al, 2016].…”

Section: Introductionmentioning

confidence: 99%

“…Several laboratory studies have confirmed that soil dusts may include much more efficient INPs than desert dusts and clay minerals [Isono and Ikebe, 1960;Fornea et al, 2009;Conen et al, 2011;O'Sullivan et al, 2014;Tobo et al, 2014]. Therefore, soil dusts may initiate the formation of ice in droplet and mixed-phase clouds.…”

Section: Introductionmentioning

confidence: 99%

Ice nucleation activity of agricultural soil dust aerosols from Mongolia, Argentina, and Germany

et al. 2016

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Soil dust particles emitted from agricultural areas contain considerable mass fractions of organic material. Also, soil dust particles may act as carriers for potentially ice‐active biological particles. In this work, we present ice nucleation experiments conducted in the Aerosol Interaction and Dynamics in the Atmosphere (AIDA) cloud chamber. We investigated the ice nucleation efficiency of four types of soil dust from different regions of the world. The results are expressed as ice nucleation active surface site (INAS) densities and presented for the immersion freezing and the deposition nucleation mode. For immersion freezing occurring at 254 K, samples from Argentina, China, and Germany show ice nucleation efficiencies which are by a factor of 10 higher than desert dusts. On average, the difference in ice nucleation efficiencies between agricultural and desert dusts becomes significantly smaller at temperatures below 247 K. In the deposition mode the soil dusts showed higher ice nucleation activity than Arizona Test Dust over a temperature range between 232 and 248 K and humidities RHice up to 125%. INAS densities varied between 109 and 1011 m−2 for these thermodynamic conditions. For one soil dust sample (Argentinian Soil), the effect of treatments with heat was investigated. Heat treatments (383 K) did not affect the ice nucleation efficiency observed at 249 K. This finding presumably excludes proteinaceous ice‐nucleating entities as the only source of the increased ice nucleation efficiency.

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“…The impact of surface coatings and aging have also been investigated for BC and dust, often showing that surface treatment generally decreases and can suppress the nucleating ability of the studied particles under atmospheric conditions [Cziczo et al, 2009;Möhler et al, 2005]. The nucleating efficiency of various other atmospheric aerosols such as bacteria [Levin and Yankofsky, 1983], organic acids [Zobrist et al, 2006], biomass burning particles [Petters et al, 2009], soil dust [O'Sullivan et al, 2014], and more recently, sea salts [Wise et al, 2012] have also been extensively studied. Most of the laboratory studies mentioned here have been connected to theory and have therefore strongly contributed to the emergence of a reliable heterogeneous ice nucleation modeling framework based on CNT.…”

Section: Introductionmentioning

confidence: 99%

A theory‐based parameterization for heterogeneous ice nucleation and implications for the simulation of ice processes in atmospheric models

Savre

Ekman

2015

JGR Atmospheres

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A new parameterization for heterogeneous ice nucleation constrained by laboratory data and based on classical nucleation theory is introduced. Key features of the parameterization include the following: a consistent and modular modeling framework for treating condensation/immersion and deposition freezing, the possibility to consider various potential ice nucleating particle types (e.g., dust, black carbon, and bacteria), and the possibility to account for an aerosol size distribution. The ice nucleating ability of each aerosol type is described using a contact angle ( ) probability density function (PDF). A new modeling strategy is described to allow the PDF to evolve in time so that the most efficient ice nuclei (associated with the lowest values) are progressively removed as they nucleate ice. A computationally efficient quasi Monte Carlo method is used to integrate the computed ice nucleation rates over both size and contact angle distributions. The parameterization is employed in a parcel model, forced by an ensemble of Lagrangian trajectories extracted from a three-dimensional simulation of a springtime low-level Arctic mixed-phase cloud, in order to evaluate the accuracy and convergence of the method using different settings. The same model setup is then employed to examine the importance of various parameters for the simulated ice production. Modeling the time evolution of the PDF is found to be particularly crucial; assuming a time-independent PDF significantly overestimates the ice nucleation rates. It is stressed that the capacity of black carbon (BC) to form ice in the condensation/immersion freezing mode is highly uncertain, in particular at temperatures warmer than −20 ∘ C. In its current version, the parameterization most likely overestimates ice initiation by BC.

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Ice nucleation by fertile soil dusts: relative importance of mineral and biogenic components

Cited by 218 publications

References 93 publications

Organic matter matters for ice nuclei of agricultural soil origin

Organic matter matters for ice nuclei of agricultural soil origin

Ice nucleation activity of agricultural soil dust aerosols from Mongolia, Argentina, and Germany

A theory‐based parameterization for heterogeneous ice nucleation and implications for the simulation of ice processes in atmospheric models

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