Your search keyword '"Campuzano-Jost, Pedro"' showing total 3 results

1. Aerosol pH indicator and organosulfate detectability from aerosol mass spectrometry measurements.

Author

Schueneman, Melinda K., Nault, Benjamin A., Campuzano-Jost, Pedro, Jo, Duseong S., Day, Douglas A., Schroder, Jason C., Palm, Brett B., Hodzic, Alma, Dibb, Jack E., and Jimenez, Jose L.

Subjects

MASS spectrometry, MASS measurement, AEROSOLS, PARTICULATE matter, AMMONIUM sulfate, CARBONACEOUS aerosols, AIRBORNE-based remote sensing

Abstract

Aerosol sulfate is a major component of submicron particulate matter (PM 1). Sulfate can be present as inorganic (mainly ammonium sulfate, AS) or organosulfate (OS). Although OS is thought to be a smaller fraction of total sulfate in most cases, recent literature argues that this may not be the case in more polluted environments. Aerodyne aerosol mass spectrometers (AMSs) measure total submicron sulfate, but it has been difficult to apportion AS vs. OS as the detected ion fragments are similar. Recently, two new methods have been proposed to quantify OS separately from AS with AMS data. We use observations collected during several airborne field campaigns covering a wide range of sources and air mass ages (spanning the continental US, marine remote troposphere, and Korea) and targeted laboratory experiments to investigate the performance and validity of the proposed OS methods. Four chemical regimes are defined to categorize the factors impacting sulfate fragmentation. In polluted areas with high ammonium nitrate concentrations and in remote areas with high aerosol acidity, the decomposition and fragmentation of sulfate in the AMS is influenced by multiple complex effects, and estimation of OS does not seem possible with current methods. In regions with lower acidity (pH > 0) and ammonium nitrate (fraction of total mass < 0.3), the proposed OS methods might be more reliable, although application of these methods often produced nonsensical results. However, the fragmentation of ambient neutralized sulfate varies somewhat within studies, adding uncertainty, possibly due to variations in the effect of organics. Under highly acidic conditions (when calculated pH < 0 and ammonium balance < 0.65), sulfate fragment ratios show a clear relationship with acidity. The measured ammonium balance (and to a lesser extent, the H y SO x+ / SO x+ AMS ratio) is a promising indicator of rapid estimation of aerosol pH < 0, including when gas-phase NH 3 and HNO 3 are not available. These results allow an improved understanding of important intensive properties of ambient aerosols. [ABSTRACT FROM AUTHOR]

Published

2021

2. Aerosol pH Indicator and Organosulfate Detectability from Aerosol Mass Spectrometry Measurements.

Author

Schueneman, Melinda K., Nault, Benjamin A., Campuzano-Jost, Pedro, Jo, Duseong S., Day, Douglas A., Schroder, Jason C., Palm, Brett B., Hodzic, Alma, Dibb, Jack E., and Jimenez, Jose L.

Subjects

MASS spectrometry, AEROSOLS, MASS measurement, AMMONIUM sulfate, PARTICULATE matter, AIRBORNE-based remote sensing

Abstract

Aerosol sulfate is a major component of submicron particulate matter (PM1). Sulfate can be present as inorganic (mainly ammonium sulfate, AS) or organic sulfate (OS). Although OS are thought to be a smaller fraction of total sulfate in most cases, recent literature argues that this may not be the case in more polluted environments. Aerodyne Aerosol Mass Spectrometers (AMS) measure total submicron sulfate, but it has been difficult to apportion AS vs. OS as the detected ion fragments are similar. Recently, two new methods have been proposed to quantify OS separately from AS with AMS data. We use observations collected during several airborne field campaigns covering a wide range of sources and airmass ages (spanning the continental US, marine remote troposphere, and Korea) and targeted laboratory experiments to investigate the performance and validity of the proposed OS methods. Four chemical regimes are defined to categorize the factors impacting sulfate fragmentation (Fig. shown in abstract). In polluted areas with high ammonium nitrate concentrations and in remote areas with high aerosol acidity, the decomposition and fragmentation of sulfate in the AMS is influenced by multiple complex effects, and estimation of OS does not seem possible with current methods. In regions with lower acidity (pH>0) and ammonium nitrate (fraction<0.3), the proposed OS methods might be more reliable, although application of these methods often produced nonsensical results. However, the fragmentation of ambient neutralized sulfate varies somewhat within studies, adding uncertainty, possibly due to variations in the effect of organics. Under highly acidic conditions, sulfate fragment ratios show a clear relationship with acidity (pH and ammonium balance). The measured ammonium balance (and to a lesser extent, the HySOx+/SOx+ AMS ratio) is a promising indicator for rapid estimation of aerosol pH < 0, including when gas-phase NH3 and HNO3 are not available. These results allow an improved understanding of important intensive properties of ambient aerosols. [ABSTRACT FROM AUTHOR]

Published

2020

3. Understanding and improving model representation of aerosol optical properties for a Chinese haze event measured during KORUS-AQ.

Author

Saide, Pablo E., Gao, Meng, Lu, Zifeng, Goldberg, Daniel L., Streets, David G., Woo, Jung-Hun, Beyersdorf, Andreas, Corr, Chelsea A., Thornhill, Kenneth L., Anderson, Bruce, Hair, Johnathan W., Nehrir, Amin R., Diskin, Glenn S., Jimenez, Jose L., Nault, Benjamin A., Campuzano-Jost, Pedro, Dibb, Jack, Heim, Eric, Lamb, Kara D., and Schwarz, Joshua P.

Subjects

OPTICAL properties, AIR quality, AEROSOLS, PARTICULATE matter, CARBONACEOUS aerosols, HEALTH impact assessment, AIR pollution, HAZE

Abstract

KORUS-AQ was an international cooperative air quality field study in South Korea that measured local and remote sources of air pollution affecting the Korean Peninsula during May–June 2016. Some of the largest aerosol mass concentrations were measured during a Chinese haze transport event (24 May). Air quality forecasts using the WRF-Chem model with aerosol optical depth (AOD) data assimilation captured AOD during this pollution episode but overpredicted surface particulate matter concentrations in South Korea, especially PM 2.5 , often by a factor of 2 or larger. Analysis revealed multiple sources of model deficiency related to the calculation of optical properties from aerosol mass that explain these discrepancies. Using in situ observations of aerosol size and composition as inputs to the optical properties calculations showed that using a low-resolution size bin representation (four bins) underestimates the efficiency with which aerosols scatter and absorb light (mass extinction efficiency). Besides using finer-resolution size bins (8–16 bins), it was also necessary to increase the refractive indices and hygroscopicity of select aerosol species within the range of values reported in the literature to achieve better consistency with measured values of the mass extinction efficiency (6.7 m 2 g -1 observed average) and light-scattering enhancement factor (f (RH)) due to aerosol hygroscopic growth (2.2 observed average). Furthermore, an evaluation of the optical properties obtained using modeled aerosol properties revealed the inability of sectional and modal aerosol representations in WRF-Chem to properly reproduce the observed size distribution, with the models displaying a much wider accumulation mode. Other model deficiencies included an underestimate of organic aerosol density (1.0 g cm -3 in the model vs. observed average of 1.5 g cm -3) and an overprediction of the fractional contribution of submicron inorganic aerosols other than sulfate, ammonium, nitrate, chloride, and sodium corresponding to mostly dust (17 %–28 % modeled vs. 12 % estimated from observations). These results illustrate the complexity of achieving an accurate model representation of optical properties and provide potential solutions that are relevant to multiple disciplines and applications such as air quality forecasts, health impact assessments, climate projections, solar power forecasts, and aerosol data assimilation. [ABSTRACT FROM AUTHOR]

Published

2020