Effect of secondary organic aerosol coating thickness on the real-time detection and characterization of biomass-burning soot by two particle mass spectrometers

Effect of secondary organic aerosol coating thickness on the real-time detection and characterization of biomass-burning soot by two particle mass spectrometers

Biomass burning is a large source of light-absorbing refractory black carbon (rBC) particles with a wide range of morphologies and sizes. The net radiative forcing from these particles is strongly dependent on the amount and composition of non-light-absorbing material internally mixed with the rB...

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Main Authors: A. T. Ahern, R. Subramanian, G. Saliba, E. M. Lipsky, N. M. Donahue, R. C. Sullivan
Format: Article
Language:English
Published: Copernicus Publications 2016-12-01
Series:Atmospheric Measurement Techniques
Online Access:http://www.atmos-meas-tech.statler/9/6117/2016/amt-9-6117-2016.pdf
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spelling doaj-00323f4b7a044adabef59e91ae87ea672020-11-24T23:47:20ZengCopernicus PublicationsAtmospheric Measurement Techniques1867-13811867-85482016-12-0196117613710.5194/amt-9-6117-2016Effect of secondary organic aerosol coating thickness on the real-time detection and characterization of biomass-burning soot by two particle mass spectrometersA. T. Ahern0R. Subramanian1G. Saliba2E. M. Lipsky3E. M. Lipsky4N. M. Donahue5R. C. Sullivan6Center for Atmospheric Particle Studies, Carnegie Mellon University, Pittsburgh, PA, 15213, USACenter for Atmospheric Particle Studies, Carnegie Mellon University, Pittsburgh, PA, 15213, USACenter for Atmospheric Particle Studies, Carnegie Mellon University, Pittsburgh, PA, 15213, USACenter for Atmospheric Particle Studies, Carnegie Mellon University, Pittsburgh, PA, 15213, USAPenn State Greater Allegheny, 4000 University Drive, McKeesport, Pennsylvania 15132, USACenter for Atmospheric Particle Studies, Carnegie Mellon University, Pittsburgh, PA, 15213, USACenter for Atmospheric Particle Studies, Carnegie Mellon University, Pittsburgh, PA, 15213, USABiomass burning is a large source of light-absorbing refractory black carbon (rBC) particles with a wide range of morphologies and sizes. The net radiative forcing from these particles is strongly dependent on the amount and composition of non-light-absorbing material internally mixed with the rBC and on the morphology of the mixed particles. Understanding how the mixing state and morphology of biomass-burning aerosol evolves in the atmosphere is critical for constraining the influence of these particles on radiative forcing and climate. We investigated the response of two commercial laser-based particle mass spectrometers, the vacuum ultraviolet (VUV) ablation LAAPTOF and the IR vaporization SP-AMS, to monodisperse biomass-burning particles as we sequentially coated the particles with secondary organic aerosol (SOA) from <i>α</i>-pinene ozonolysis. We studied three mobility-selected soot core sizes, each with a number of successively thicker coatings of SOA applied. Using IR laser vaporization, the SP-AMS had different changes in sensitivity to rBC compared to potassium as a function of applied SOA coatings. We show that this is due to different effective beam widths for the IR laser vaporization region of potassium versus black carbon. The SP-AMS's sensitivity to black carbon (BC) mass was not observed to plateau following successive SOA coatings, despite achieving high OA : BC mass ratios greater than 9. We also measured the ion fragmentation pattern of biomass-burning rBC and found it changed only slightly with increasing SOA mass. The average organic matter ion signal measured by the LAAPTOF demonstrated a positive correlation with the condensed SOA mass on individual particles, despite the inhomogeneity of the particle core compositions. This demonstrates that the LAAPTOF can obtain quantitative mass measurements of aged soot-particle composition from realistic biomass-burning particles with complex morphologies and composition.http://www.atmos-meas-tech.statler/9/6117/2016/amt-9-6117-2016.pdf
collection DOAJ
language English
format Article
sources DOAJ
author A. T. Ahern
R. Subramanian
G. Saliba
E. M. Lipsky
E. M. Lipsky
N. M. Donahue
R. C. Sullivan
spellingShingle A. T. Ahern
R. Subramanian
G. Saliba
E. M. Lipsky
E. M. Lipsky
N. M. Donahue
R. C. Sullivan
Effect of secondary organic aerosol coating thickness on the real-time detection and characterization of biomass-burning soot by two particle mass spectrometers
Atmospheric Measurement Techniques
author_facet A. T. Ahern
R. Subramanian
G. Saliba
E. M. Lipsky
E. M. Lipsky
N. M. Donahue
R. C. Sullivan
author_sort A. T. Ahern
title Effect of secondary organic aerosol coating thickness on the real-time detection and characterization of biomass-burning soot by two particle mass spectrometers
title_short Effect of secondary organic aerosol coating thickness on the real-time detection and characterization of biomass-burning soot by two particle mass spectrometers
title_full Effect of secondary organic aerosol coating thickness on the real-time detection and characterization of biomass-burning soot by two particle mass spectrometers
title_fullStr Effect of secondary organic aerosol coating thickness on the real-time detection and characterization of biomass-burning soot by two particle mass spectrometers
title_full_unstemmed Effect of secondary organic aerosol coating thickness on the real-time detection and characterization of biomass-burning soot by two particle mass spectrometers
title_sort effect of secondary organic aerosol coating thickness on the real-time detection and characterization of biomass-burning soot by two particle mass spectrometers
publisher Copernicus Publications
series Atmospheric Measurement Techniques
issn 1867-1381
1867-8548
publishDate 2016-12-01
description Biomass burning is a large source of light-absorbing refractory black carbon (rBC) particles with a wide range of morphologies and sizes. The net radiative forcing from these particles is strongly dependent on the amount and composition of non-light-absorbing material internally mixed with the rBC and on the morphology of the mixed particles. Understanding how the mixing state and morphology of biomass-burning aerosol evolves in the atmosphere is critical for constraining the influence of these particles on radiative forcing and climate. We investigated the response of two commercial laser-based particle mass spectrometers, the vacuum ultraviolet (VUV) ablation LAAPTOF and the IR vaporization SP-AMS, to monodisperse biomass-burning particles as we sequentially coated the particles with secondary organic aerosol (SOA) from <i>α</i>-pinene ozonolysis. We studied three mobility-selected soot core sizes, each with a number of successively thicker coatings of SOA applied. Using IR laser vaporization, the SP-AMS had different changes in sensitivity to rBC compared to potassium as a function of applied SOA coatings. We show that this is due to different effective beam widths for the IR laser vaporization region of potassium versus black carbon. The SP-AMS's sensitivity to black carbon (BC) mass was not observed to plateau following successive SOA coatings, despite achieving high OA : BC mass ratios greater than 9. We also measured the ion fragmentation pattern of biomass-burning rBC and found it changed only slightly with increasing SOA mass. The average organic matter ion signal measured by the LAAPTOF demonstrated a positive correlation with the condensed SOA mass on individual particles, despite the inhomogeneity of the particle core compositions. This demonstrates that the LAAPTOF can obtain quantitative mass measurements of aged soot-particle composition from realistic biomass-burning particles with complex morphologies and composition.
url http://www.atmos-meas-tech.statler/9/6117/2016/amt-9-6117-2016.pdf
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