Influence of Environmentally Relevant Physicochemical Conditions on a Highly Efficient Inorganic Ice Nucleating Particle

Ganguly, Mainak; Dib, Simon; Kurien, Uday; Rangel-Alvarado, Rodrigo Benjamin; Miyahara, Yoichi; Ariya, Parisa A.

doi:10.1021/acs.jpcc.8b03551

Cited by 11 publications

(18 citation statements)

References 88 publications

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“…There are rarely any reports so far for heterogeneous ice nucleation in the immersion mode of ZnO. We reported previously that ZnO reduced INE of purely inorganic and environmentally available ice nucleating particles. In this study, we found that plastic nano- and microparticles decreased the INE of ZnO.…”

Section: Resultsmentioning

confidence: 84%

“…Electron microscopy imaging did not indicate the roughness of the plastic particles. Therefore, it is likely that a mechanism related to the low lattice mismatch between ice and plastic particles is attributed to enhancement of INE. , …”

Section: Resultsmentioning

confidence: 99%

“…Therefore, it is likely that a mechanism related to the low lattice mismatch between ice and plastic particles is attributed to enhancement of INE. (58,61) The difference of the INE of plastic particles with several contaminants was likely the outcome of the above factors. We herein investigated three types of plastic particles at various conditions to understand the tentative effect of the nano-and microplastics in the atmosphere in the context of INE.…”

Section: Effect Of Co-contaminants On Ine Of Nano-and Microplastics: Comparison Of Ine Between Different Synthetic Methods Of the Plasticmentioning

confidence: 99%

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Ice Nucleation of Model Nanoplastics and Microplastics: A Novel Synthetic Protocol and the Influence of Particle Capping at Diverse Atmospheric Environments

Ganguly

Ariya

2019

ACS Earth Space Chem.

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Little is known about airborne atmospheric aerosols containing emerging contaminants such as nano-and microplastics. A novel, minimum energy usage, synthetic protocol of plastic micro/nanoparticles was herein developed. Stable plastic hydrosols were synthesized and characterized using three different types of plastics. The ice nucleation efficiency (INE) was investigated in both normal and synthetic seawater to mimic environmental ice nucleation. Among the three tested plastic precursors (low-density polyethylene, high-density polyethylene, and polypropylene), polypropylene produced the highest particle density with narrow particle size distribution. The change of size, shape, surface charge, and electronic behavior of the plastic nano-and microparticles accounted for the altered INE. The effects of environmental factors such as particle acidity and temperature on ice nucleation were also examined. An increase in pH increased INE due to an increased particle density (number of particles per unit volume), whereas increased temperature decreased INE significantly due to aggregation (attaching particles to produce a larger particle). Four types of capping were used on the surfaces of nano-and microplastics to investigate how the plastics act to nucleate ice when mixed with different particles. They include (a) ZnO as an emerging metal contaminant, (b) kaolin as a clay mineral, (c) HgCl2 as a toxic ionic water pollutant, and (d) phenanthrene as a polycyclic aromatic hydrocarbon. Capping by ZnO and HgCl2 decreased the INE of plastic nano-and microparticles, whereas kaolin and phenanthrene enhanced INE significantly. The association of contaminants to micro-and nanoplastics changes INE likely due to water affinity, surface buckling, and lattice mismatch energy of ice, affecting ice nuclei formation processes. The observed differential physicochemical behaviors of nano-and microplastics, with and without co-contaminant cappings, provide further insights to understand natural environmental ice nucleation and precipitation events. Our work shows that future emissions of nano-and microplastics may become important for cloud formation and thus anthropogenic climate change.

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Section: Resultsmentioning

confidence: 84%

Section: Resultsmentioning

confidence: 99%

Section: Effect Of Co-contaminants On Ine Of Nano-and Microplastics: Comparison Of Ine Between Different Synthetic Methods Of the Plasticmentioning

confidence: 99%

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Ice Nucleation of Model Nanoplastics and Microplastics: A Novel Synthetic Protocol and the Influence of Particle Capping at Diverse Atmospheric Environments

Ganguly

Ariya

2019

ACS Earth Space Chem.

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“…Kaolin contaminated with CuCl 2 was a highly efficient adsorbent, able to take up gaseous elemental Hg within seconds at room temperature (16.33 mg g −1 of Cu from inductively coupled plasma mass spectrometry analysis). Previously, we synthesized Fe composite BHFe from the reduction of FeCl 2 by NaBH 4 followed by aerial oxidation. BHFe is an efficient Hg II adsorbent and produced a highly efficient ice‐nucleating particle HgBHFe (maghemite@Hg 2 Cl 2 ) after the uptake of HgCl 2 .…”

Section: Resultsmentioning

confidence: 99%

“…Microphysics of ice nucleation to obtain furtherinsightso n potential reaction mechanism(s) Kaolin contaminated with CuCl 2 was ah ighly efficient adsorbent, able to take up gaseous elemental Hg within seconds at room temperature (16.33 mg g À1 of Cu from inductively coupled plasma mass spectrometry analysis). Previously, [27,28] we synthesized Fe composite BHFe from the reductiono fF eCl 2 by NaBH 4 followed by aerial oxidation. BHFe is an efficient Hg II adsorbenta nd produced ah ighly efficient ice-nucleating particle HgBHFe (maghemite@Hg 2 Cl 2 )a fter the uptake of HgCl 2 .I th as www.chemsuschem.org thus been shown that ionic Hg (in associationw ith Cl À )e nhanced the ice nucleation efficiency of BHFe significantly.…”

Section: Effect Of Selectedsalts and Halides On Hg 0 Adsorptiono N Kamentioning

confidence: 99%

Natural Kaolin: Sustainable Technology for the Instantaneous and Energy‐Neutral Recycling of Anthropogenic Mercury Emissions

et al. 2019

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Kaolin, a natural and inexpensive clay mineral, is ubiquitous in soil, dirt, and airborne particles. Amongst four commonly available clay minerals, kaolin, as a result of its layered structure, is the most efficient natural gaseous Hg adsorbent to date (Langmuir maximum adsorption capacity Qm=574.08 μg g−1 and Freundlich Qm=756.49 μg g−1). The Hg uptake proceeds by homogeneous monolayer and heterogeneous processes. Hg physisorption on kaolin occurs in the dark, yet the adsorption rate is enhanced upon irradiation. The effects of several metal complexes, salts, halides and solvents on the Hg uptake were examined. The addition of CuCl2 particles leads to a significant enhancement of the Hg uptake capacity (>30 times) within second timescales and without irradiation. The physisorption with kaolin is switched to chemisorption upon the addition of CuCl2 to kaolin. This process is entirely reversible upon the addition of Zn/Sn granules at room temperature without any added energy. However, the investment of a small amount of renewable energy can speed up the process. This technology demonstrates the facile and efficient capture and recycling of elemental Hg0 from air. A wide range of metal particles and diverse physicochemical processes, which include the microphysics of nucleation, are herein examined to explore the potential reaction mechanism by using a suite of complementary analytical techniques. These new mechanistic insights open a new era of energy‐neutral environmental remediation based on natural soil/airborne particles.

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Determination of nano and microplastic particles in hypersaline lakes by multiple methods

Pashaei

Loiselle

Leone

et al. 2021

Environ Monit Assess

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Influence of Environmentally Relevant Physicochemical Conditions on a Highly Efficient Inorganic Ice Nucleating Particle

Cited by 11 publications

References 88 publications

Ice Nucleation of Model Nanoplastics and Microplastics: A Novel Synthetic Protocol and the Influence of Particle Capping at Diverse Atmospheric Environments

Ice Nucleation of Model Nanoplastics and Microplastics: A Novel Synthetic Protocol and the Influence of Particle Capping at Diverse Atmospheric Environments

Natural Kaolin: Sustainable Technology for the Instantaneous and Energy‐Neutral Recycling of Anthropogenic Mercury Emissions

Determination of nano and microplastic particles in hypersaline lakes by multiple methods

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