Laboratory studies of fresh and aged biomass burning aerosols emitted from east African biomass fuels – Part 2: Chemical properties and characterization

Smith, Damon M.; Cui, Tianqu; Fiddler, Marc N.; Pokhrel, Rudra; Surratt, Jason D.; Bililign, Solomon

doi:10.5194/acp-2019-1160

Cited by 3 publications

(3 citation statements)

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“…This work was conducted at the North Carolina Agricultural and Technical State University (NCAT) indoor burning facility that has a well-equipped environmental chamber for the measurement of fresh and aged aerosol, which is described in detail elsewhere (Smith et al 2019(Smith et al , 2020a(Smith et al , 2020b. BB aerosol was generated by the combustion of biomass fuel in a tube furnace.…”

Section: Ncat Burning Facilitymentioning

confidence: 99%

Impact of combustion conditions on physical and morphological properties of biomass burning aerosol

Pokhrel

Gordon

Fiddler

et al. 2020

Aerosol Science and Technology

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The study of biomass burning particle density provides information on aging, new particle formation, transport properties, and is an important parameter in aerosol impacts modeling. Density is used in mass closure techniques to estimate the temporal resolution of particulate mass concentrations. However, the study of BB particle density as a function of burning conditions is still limited. Laboratory measurement of six sub-Saharan African biomass fuels burned under a range of conditions, from pure smoldering to pure flaming conditions, is presented. Smoldering-dominated burning (modified combustion efficiency (MCE) < 0.9) particles has a very narrow range of effective density (q eff) 1.03 g cm À3 to 1.21 g cm À3 and a mass mobility exponent (D fm) of $3 (2.97 ± 0.05), indicating that they are spherical particles. For the flaming-dominated burning (MCE >0.95) particles, show a size dependent q eff for all six different fuels. In this case, the mean and standard deviation of the q eff decreased with increasing size, from (0.94 ± 0.21) g cm À3 at a mobility diameter of 80 nm to (0.31 ± 0.07) g cm À3 at a mobility diameter of 400 nm. The size-dependent q eff of flamingdominated aerosol suggests the fractal nature of freshly emitted particles. The relationship between D fm and the MCE shows three distinct morphology regimes, which we define as the spherical particle, the transition, and the fractal regime. Our proposed relationship of D fm with the MCE can be used as a tool to assess the applicability of Mie theory for optical closure calculations in the absence of particle morphological information.

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Section: Ncat Burning Facilitymentioning

confidence: 99%

Impact of combustion conditions on physical and morphological properties of biomass burning aerosol

Pokhrel

Gordon

Fiddler

et al. 2020

Aerosol Science and Technology

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“…on chemical composition and characterization published in ACPD (Smith et al, 2020). Further integration of the two manuscripts will be done, and summaries from Part 2 will be incorporated into the revised manuscript.…”

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Authors Response

Bililign¹

2020

Preprint

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The full response is attached as a pdf file with figures. RESPONSES to REFEREE #1 The paper summarizes results on optical properties of aerosols generated by burning of 3 common fuels in Africa. Some measurements were carried out on fresh BBOA, some on BBOA aged in the dark, some on photooxidized BBOA in the presence or absence of additional VOCs (typical urban aromatics). Fuels were burned at low (500 C) and high (800 C) temperatures. Non-refractory chemical composition of the aerosol was also measured, although not really discussed here. Single scattering albedo data, determined on size-selected aerosols, at mid-visible confirmed production of more ab-C1 ACPD Interactive comment Printer-friendly version Discussion paper sorbing aerosols under high temperatures. There was not a strong wavelength dependence to SSA between 500-570 nm. Dark aging of the BBOA resulted in increase in SSA possibly due to condensation of SOA and increase in the scattering cross section. The novelty of the experiment is in the selection of the fuels. However, I see some flaws in the approach (contribution of multiply charged particles was not corrected for in Mie calculations); the paper does not seem complete without the description of the compositional measurements (some conclusions are drawn on the composition of SOA without providing any support; there were no measurements of BC, yet overall refractive indices were estimated to use in Mie calculations); last the chamber oxidation experiments in the presence of additional VOCs don't seem to have worked. There were also several sentences that were confusing and need to be rephrased/clarified. Overall, I don't find the quality of this paper appropriate for ACP and cannot support any revisions. AUTHORS RESPONSE: We thank the reviewer for valuable and helpful suggestions. Embarrassing grammatical errors and sentences that seemed confusing will be corrected in the revision and changes made to the manuscript are provided here. Detailed responses are provided on the scientific questions raised. The authors feel that the reviewer either misunderstood our descriptions and overlooked some aspects of the paper. We will show this is indeed true in our detailed responses with relevant references to each question and comment. We feel that there is rush to dismiss and devalue the work and undermine the paper instead of giving us a chance to respond and clarify our claims. We hope our responses and explanations will convince the referee to make a different final determination. Three main issues raised by the reviewer in his/her the first paragraph is discussed below: A. "Non-refractory chemical composition of the aerosol was also measured, although not really discussed here"

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“…So, we think more studies are needed on biomass combustion. This work is presented as a two-part study, where this part focused on optical properties and chemical composition and characterization is presented in Part II, which is published in ACPD and we will refer the reviewer to the second part for a detailed discussion (Smith et al, 2020). Further integration of the two manuscripts will be done, and summaries from Part 2 will be incorporated into the revised manuscript.…”

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Response to Anonymous Reviewer #2

Bililign¹

2020

Preprint

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This manuscript presents measurements of single scattering albedo (SSA) of sizeselected aerosols emitted from controlled combustion of African biomass fuels under three conditions: fresh emissions, dark aged aerosols and photo-chemically aged aerosols. Three types of wood fuels were combusted in a tube furnace at two different temperatures (500 C and 800 C) and an indoor smog chamber was used to age C1 ACPD Interactive comment Printer-friendly version Discussion paper aerosols in clean and polluted (VOC rich) environments. AUTHORS RESPONSE: We thank the reviewer for the time he/she took to provide us with valuable suggestions. The authors feel that the reviewer either misunderstood our descriptions and overlooked some aspects of the paper. We will show this is indeed true in our detailed responses with relevant references to each question and comment. We feel that there is rush to dismiss and devalue the work and undermine the paper instead of giving us a chance to respond and clarify our claims. We hope our responses and explanations will convince the referee to make a different final determination.

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Laboratory studies of fresh and aged biomass burning aerosols emitted from east African biomass fuels – Part 2: Chemical properties and characterization

Cited by 3 publications

References 28 publications

Impact of combustion conditions on physical and morphological properties of biomass burning aerosol

Impact of combustion conditions on physical and morphological properties of biomass burning aerosol

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