Liquid-liquid phase separation in atmospherically relevant particles consisting of organic species and inorganic salts

Laboratory studies of liquid-liquid phase separation in particles containing organic species and inorganic salts of atmospheric relevance are reviewed. The oxygen-to-carbon elemental ratio (O:C) of the organic component appears to be the most useful parameter for estimating, to a first approximation...

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Published in	International reviews in physical chemistry Vol. 33; no. 1; pp. 43 - 77
Main Authors	You, Yuan, Smith, Mackenzie L., Song, Mijung, Martin, Scot T., Bertram, Allan K.
Format	Journal Article
Language	English
Published	Abingdon Taylor & Francis 02.01.2014 Taylor & Francis Ltd
Subjects	Approximation atmospheric particles Fluids Humidity Inorganic salts liquid-liquid phase separation Mathematical analysis Morphology Organic materials Phase separation Phase transitions Physical chemistry Relative humidity Salt salting out secondary organic material Trends
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Abstract	Laboratory studies of liquid-liquid phase separation in particles containing organic species and inorganic salts of atmospheric relevance are reviewed. The oxygen-to-carbon elemental ratio (O:C) of the organic component appears to be the most useful parameter for estimating, to a first approximation, the occurrence of liquid-liquid phase separation and the separation relative humidity (SRH) in these particles. A trend of decreasing SRH for increasing O:C was found for simple organic-inorganic mixtures (<11 species). Phase separation in particles composed of laboratory-produced secondary organic material and sulphate species and in ambient particles is generally consistent with this trend. A further constraint is that liquid-liquid phase separation was always observed for O:C < 0.5 and was never observed for O:C ≥ 0.8. For organic materials of intermediate O:C ranging from 0.5 to 0.8, phase separation in simple organic-inorganic mixtures was influenced by the organic functional groups represented. The organic-to-inorganic mass ratio (OIR) affected the occurrence of liquid-liquid phase separation in a small number of cases. A dependence on salt type was observed with 87% of the studied organics exhibiting the following trend in SRH values: (NH 4 ) 2 SO 4 ≥ NH 4 HSO 4 ≥ NaCl ≥ NH 4 NO 3 , consistent with previous salting-out studies and the Hofmeister series. Liquid-liquid phase separation does not appear to be strongly influenced by the number of species making up the organic material. The morphology of phase separated particles appears to depend on composition, including O:C of the organic material, the inorganic salt and the OIR.
AbstractList	Laboratory studies of liquid-liquid phase separation in particles containing organic species and inorganic salts of atmospheric relevance are reviewed. The oxygen-to-carbon elemental ratio (O:C) of the organic component appears to be the most useful parameter for estimating, to a first approximation, the occurrence of liquid-liquid phase separation and the separation relative humidity (SRH) in these particles. A trend of decreasing SRH for increasing O:C was found for simple organic-inorganic mixtures (<11 species). Phase separation in particles composed of laboratory-produced secondary organic material and sulphate species and in ambient particles is generally consistent with this trend. A further constraint is that liquid-liquid phase separation was always observed for O:C < 0.5 and was never observed for O:C ≥ 0.8. For organic materials of intermediate O:C ranging from 0.5 to 0.8, phase separation in simple organic-inorganic mixtures was influenced by the organic functional groups represented. The organic-to-inorganic mass ratio (OIR) affected the occurrence of liquid-liquid phase separation in a small number of cases. A dependence on salt type was observed with 87% of the studied organics exhibiting the following trend in SRH values: (NH^sub 4^)^sub 2^SO^sub 4^ ≥ NH^sub 4^HSO^sub 4^ ≥ NaCl ≥ NH^sub 4^NO^sub 3^, consistent with previous salting-out studies and the Hofmeister series. Liquid-liquid phase separation does not appear to be strongly influenced by the number of species making up the organic material. The morphology of phase separated particles appears to depend on composition, including O:C of the organic material, the inorganic salt and the OIR. [PUBLICATION ABSTRACT] Laboratory studies of liquid-liquid phase separation in particles containing organic species and inorganic salts of atmospheric relevance are reviewed. The oxygen-to-carbon elemental ratio (O:C) of the organic component appears to be the most useful parameter for estimating, to a first approximation, the occurrence of liquid-liquid phase separation and the separation relative humidity (SRH) in these particles. A trend of decreasing SRH for increasing O:C was found for simple organic-inorganic mixtures (<11 species). Phase separation in particles composed of laboratory-produced secondary organic material and sulphate species and in ambient particles is generally consistent with this trend. A further constraint is that liquid-liquid phase separation was always observed for O:C < 0.5 and was never observed for O:C greater than or equal to 0.8. For organic materials of intermediate O:C ranging from 0.5 to 0.8, phase separation in simple organic-inorganic mixtures was influenced by the organic functional groups represented. The organic-to-inorganic mass ratio (OIR) affected the occurrence of liquid-liquid phase separation in a small number of cases. A dependence on salt type was observed with 87% of the studied organics exhibiting the following trend in SRH values: (NH sub(4)) sub(2)SO sub(4 ) greater than or equal to NH sub(4)HSO sub(4 ) greater than or equal to NaCl greater than or equal to NH sub(4)NO sub(3), consistent with previous salting-out studies and the Hofmeister series. Liquid-liquid phase separation does not appear to be strongly influenced by the number of species making up the organic material. The morphology of phase separated particles appears to depend on composition, including O:C of the organic material, the inorganic salt and the OIR. Laboratory studies of liquid-liquid phase separation in particles containing organic species and inorganic salts of atmospheric relevance are reviewed. The oxygen-to-carbon elemental ratio (O:C) of the organic component appears to be the most useful parameter for estimating, to a first approximation, the occurrence of liquid-liquid phase separation and the separation relative humidity (SRH) in these particles. A trend of decreasing SRH for increasing O:C was found for simple organic-inorganic mixtures (<11 species). Phase separation in particles composed of laboratory-produced secondary organic material and sulphate species and in ambient particles is generally consistent with this trend. A further constraint is that liquid-liquid phase separation was always observed for O:C < 0.5 and was never observed for O:C ≥ 0.8. For organic materials of intermediate O:C ranging from 0.5 to 0.8, phase separation in simple organic-inorganic mixtures was influenced by the organic functional groups represented. The organic-to-inorganic mass ratio (OIR) affected the occurrence of liquid-liquid phase separation in a small number of cases. A dependence on salt type was observed with 87% of the studied organics exhibiting the following trend in SRH values: (NH 4 ) 2 SO 4 ≥ NH 4 HSO 4 ≥ NaCl ≥ NH 4 NO 3 , consistent with previous salting-out studies and the Hofmeister series. Liquid-liquid phase separation does not appear to be strongly influenced by the number of species making up the organic material. The morphology of phase separated particles appears to depend on composition, including O:C of the organic material, the inorganic salt and the OIR.
Author	Song, Mijung Smith, Mackenzie L. You, Yuan Martin, Scot T. Bertram, Allan K.
Author_xml	– sequence: 1 givenname: Yuan surname: You fullname: You, Yuan organization: Department of Chemistry, University of British Columbia – sequence: 2 givenname: Mackenzie L. surname: Smith fullname: Smith, Mackenzie L. organization: School of Engineering and Applied Science, Harvard University – sequence: 3 givenname: Mijung surname: Song fullname: Song, Mijung organization: Department of Chemistry, University of British Columbia – sequence: 4 givenname: Scot T. surname: Martin fullname: Martin, Scot T. email: scot_martin@harvard.edu organization: Department of Earth and Planetary Science, Harvard University – sequence: 5 givenname: Allan K. surname: Bertram fullname: Bertram, Allan K. email: bertram@chem.ubc.ca organization: Department of Chemistry, University of British Columbia
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Snippet	Laboratory studies of liquid-liquid phase separation in particles containing organic species and inorganic salts of atmospheric relevance are reviewed. The...
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SubjectTerms	Approximation atmospheric particles Fluids Humidity Inorganic salts liquid-liquid phase separation Mathematical analysis Morphology Organic materials Phase separation Phase transitions Physical chemistry Relative humidity Salt salting out secondary organic material Trends
Title	Liquid-liquid phase separation in atmospherically relevant particles consisting of organic species and inorganic salts
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