pH Dependence of Liquid–Liquid Phase Separation in Organic Aerosol

Losey, Delanie J.; Parker, Robert G.; Freedman, Miriam Arak

doi:10.1021/acs.jpclett.6b01621

Cited by 72 publications

(109 citation statements)

References 49 publications

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“…The change in correlation strength with increasing RH suggests that uptake is limited by the term Γ sol + Γ rxn ( and/or ) at low RH, but becomes limited by a different process, such as α as water availability increases (e.g., Bertram & Thornton, ; Thornton & Abbatt, ). The exact RH associated with this sensitivity change is thought to depend on the deliquescence point of each aerosol type and its propensity to form supersaturated liquids (e.g., Kane et al, ), which can be impacted by aerosol acidity and organics (e.g., Losey et al, ). In addition, several studies have observed the opposite, decreasing trend in γ (N 2 O 5 ) with RH on highly acidic sulfuric acid particles (Fried et al, ; Hallquist et al, ; Hu & Abbatt, ; Kane et al, ; Mozurkewich & Calvert, ), which supports an alternative, acid‐catalyzed mechanism discussed in section 4.2.5.…”

Section: Discussionmentioning

confidence: 99%

Heterogeneous N₂O₅ Uptake During Winter: Aircraft Measurements During the 2015 WINTER Campaign and Critical Evaluation of Current Parameterizations

et al. 2018

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Nocturnal dinitrogen pentoxide (N2O5) heterogeneous chemistry impacts regional air quality and the distribution and lifetime of tropospheric oxidants. Formed from the oxidation of nitrogen oxides, N2O5 is heterogeneously lost to aerosol with a highly variable reaction probability, γ(N2O5), dependent on aerosol composition and ambient conditions. Reaction products include soluble nitrate (HNO3 or NO3−) and nitryl chloride (ClNO2). We report the first‐ever derivations of γ(N2O5) from ambient wintertime aircraft measurements in the critically important nocturnal residual boundary layer. Box modeling of the 2015 Wintertime INvestigation of Transport, Emissions, and Reactivity (WINTER) campaign over the eastern United States derived 2,876 individual γ(N2O5) values with a median value of 0.0143 and range of 2 × 10−5 to 0.1751. WINTER γ(N2O5) values exhibited the strongest correlation with aerosol water content, but weak correlations with other variables, such as aerosol nitrate and organics, suggesting a complex, nonlinear dependence on multiple factors, or an additional dependence on a nonobserved factor. This factor may be related to aerosol phase, morphology (i.e., core shell), or mixing state, none of which are commonly measured during aircraft field studies. Despite general agreement with previous laboratory observations, comparison of WINTER data with 14 literature parameterizations (used to predict γ(N2O5) in chemical transport models) confirms that none of the current methods reproduce the full range of γ(N2O5) values. Nine reproduce the WINTER median within a factor of 2. Presented here is the first field‐based, empirical parameterization of γ(N2O5), fit to WINTER data, based on the functional form of previous parameterizations.

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Section: Discussionmentioning

confidence: 99%

Heterogeneous N₂O₅ Uptake During Winter: Aircraft Measurements During the 2015 WINTER Campaign and Critical Evaluation of Current Parameterizations

et al. 2018

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“…Hundreds of studies using electron microscopy and X‐ray spectroscopy methods to investigate aerosol particles have been published over the years, ranging from studies characterizing the constituents of specific types of aerosol, such as marine, mineral, dust, and biomass (Buseck & Pósfai, ; Li et al, ; Pósfai et al, , ) to those focused specifically on characterizing per‐particle composition and morphology (Deboudt et al, ; Pósfai et al, ), phase transitions (Wise et al, ), hygroscopic behavior (Okada, ; Semeniuk et al, ), phase separation (Ault et al, ; Freedman, ; Losey et al, ; O'Brien et al, ; You et al, ), and other important aerosol physicochemical properties that impact mixing state. However, only in the past few years have these methods begun to be used to quantify aerosol mixing state, the examples of which are discussed later in section .…”

Section: Measurement Techniques For Aerosol Mixing Statementioning

confidence: 99%

Aerosol Mixing State: Measurements, Modeling, and Impacts

Riemer

Ault

West

et al. 2019

Reviews of Geophysics

271

287

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Atmospheric aerosols are complex mixtures of different chemical species, and individual particles exist in many different shapes and morphologies. Together, these characteristics contribute to the aerosol mixing state. This review provides an overview of measurement techniques to probe aerosol mixing state, discusses how aerosol mixing state is represented in atmospheric models at different scales, and synthesizes our knowledge of aerosol mixing state's impact on climate‐relevant properties, such as cloud condensation and ice nucleating particle concentrations, and aerosol optical properties. We present these findings within a framework that defines aerosol mixing state along with appropriate mixing state metrics to quantify it. Future research directions are identified, with a focus on the need for integrating mixing state measurements and modeling.

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“…Few methods can directly measure the pH of aerosol (Rindelaub et al, 2016;Craig et al, 2018;Wei et al, 2018), so aerosol acidity is usually presented using indirect proxies such as ion balance (cationto-anion (Yao et al, 2006;Du et al, 2010;Zhou et al, 2017). However, these indirect methods can lead to substantial uncertainty in acidity assessment (Hennigan et al, 2015;Guo et al, 2016;Murphy et al, 2017). Calculation of pH through thermodynamic modelling such as E-AIM (Clegg et al, 1998) and ISORROPIA II (Fountoukis and Nenes, 2007), with the input of reliable chemical compositions of the aerosol and at least one semi-volatile gas and meteorological data, has been shown to be a more rigorous approach to calculate the pH of aerosol liquid water.…”

Section: Introductionmentioning

confidence: 99%

“…Calculation of pH through thermodynamic modelling such as E-AIM (Clegg et al, 1998) and ISORROPIA II (Fountoukis and Nenes, 2007), with the input of reliable chemical compositions of the aerosol and at least one semi-volatile gas and meteorological data, has been shown to be a more rigorous approach to calculate the pH of aerosol liquid water. Murphy et al (2017) and Song et al (2018) both showed that the constraint from phase partitioning of NH 3 /NH + 4 should be included in calculations using aerosol thermodynamic models to get reliable pH calculations, which indicates that NH 3 observation can greatly improve the reliability of the aerosol acidity assessment.…”

Section: Introductionmentioning

confidence: 99%

The sensitivity of PM<sub>2.5</sub> acidity to meteorological parameters and chemical composition changes: 10-year records from six Canadian monitoring sites

Tao

Murphy

2019

Atmos. Chem. Phys.

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Abstract. Aerosol pH is difficult to measure directly but can be calculated if the chemical composition is known with sufficient accuracy and precision to calculate the aerosol water content and the H+ concentration through the equilibrium among acids and their conjugate bases. In practical terms, simultaneous measurements of at least one semi-volatile constituent, e.g. NH3 or HNO3, are required to provide a constraint on the calculation of pH. Long-term records of aerosol pH are scarce due to the limited monitoring of NH3 in conjunction with PM2.5. In this study, 10-year (2007–2016) records of pH of PM2.5 at six eastern Canadian sites were calculated using the E-AIM II model with the input of gaseous NH3, gaseous HNO3 and major water-soluble inorganic ions in PM2.5 provided by Canada's National Air Pollution Surveillance (NAPS) Program. Clear seasonal cycles of aerosol pH were found with lower pH (∼2) in summer and higher pH (∼3) in winter consistently across all six sites, while the day-to-day variations of aerosol pH were higher in winter compared to summer. Tests of the sensitivity of aerosol pH to meteorological parameters demonstrate that the changes in ambient temperature largely drive the seasonal cycle of aerosol pH. The sensitivity of pH to chemical composition shows that pH has different responses to the changes in chemical composition in different seasons. During summertime, aerosol pH was mainly determined by temperature with limited impact from changes in NHx or sulfate concentrations. However, in wintertime, both meteorological parameters and chemical composition contribute to the variations in aerosol pH, resulting in the larger variation during wintertime. This study reveals that the sensitivity of aerosol pH to chemical composition is distinctly different under different meteorological conditions and needs to be carefully examined for any particular region.

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pH Dependence of Liquid–Liquid Phase Separation in Organic Aerosol

Cited by 72 publications

References 49 publications

Heterogeneous N₂O₅ Uptake During Winter: Aircraft Measurements During the 2015 WINTER Campaign and Critical Evaluation of Current Parameterizations

Heterogeneous N₂O₅ Uptake During Winter: Aircraft Measurements During the 2015 WINTER Campaign and Critical Evaluation of Current Parameterizations

Aerosol Mixing State: Measurements, Modeling, and Impacts

The sensitivity of PM<sub>2.5</sub> acidity to meteorological parameters and chemical composition changes: 10-year records from six Canadian monitoring sites

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pH Dependence of Liquid–Liquid Phase Separation in Organic Aerosol

Cited by 72 publications

References 49 publications

Heterogeneous N2O5 Uptake During Winter: Aircraft Measurements During the 2015 WINTER Campaign and Critical Evaluation of Current Parameterizations

Heterogeneous N2O5 Uptake During Winter: Aircraft Measurements During the 2015 WINTER Campaign and Critical Evaluation of Current Parameterizations

Aerosol Mixing State: Measurements, Modeling, and Impacts

The sensitivity of PM&lt;sub&gt;2.5&lt;/sub&gt; acidity to meteorological parameters and chemical composition changes: 10-year records from six Canadian monitoring sites

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Heterogeneous N₂O₅ Uptake During Winter: Aircraft Measurements During the 2015 WINTER Campaign and Critical Evaluation of Current Parameterizations

Heterogeneous N₂O₅ Uptake During Winter: Aircraft Measurements During the 2015 WINTER Campaign and Critical Evaluation of Current Parameterizations

The sensitivity of PM<sub>2.5</sub> acidity to meteorological parameters and chemical composition changes: 10-year records from six Canadian monitoring sites