Optical Properties, Chemical Composition and the Toxicological Potential of Urban Particulate Matter

Particulate matter (PM) is grouped as coarse, fine, and ultrafine particles (UFPs) with aerodynamic diameters of 2.5 to 10 μm (PM10), <2.5 μm (PM2.5), and <0.1 μm (PM0.1), respectively. The course and fine fractions have been well characterised from numerous aspects, including potential environmental hazard. However, more and more studies are targeted to the UFP fraction, as they bind relatively higher concentrations of potentially toxic materials and they might penetrate through cell biological barriers, posing higher risk to the biota. In our study, ecotoxic potential of size-fractionated urban aerosol was evaluated, using the kinetic version of the Vibrio fischeri bioluminescence inhibition bioassay. The kinetic protocol makes it possible to avoid false ecotoxicity readings which might appear in case of coloured and/or turbid samples. Our results showed that all PM fractions elucidated significant toxic response, highest toxicity was experienced in the range of 0.25/0.5μm and 0.5/1 μm (with the EC50s of 7.07 and 7.8%). Ecotoxicity in general followed the typical pattern of number size distributions of submicron particles experienced in Europe.

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“…Recent studies involve, among others, urban dust (e.g. [13][14][15]), traffic-related emissions (e.g. [16,17]) or fly ash (e.g.…”

Section: Introductionmentioning

confidence: 99%

Assessing Ecotoxicity of Size-fractionated Airborne Particulate Matter

et al. 2019

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“…Different kinds of atmospheric aerosols have different influences on climate [1,2], air quality [3], and human health [4]. One of the most important components of atmospheric aerosols is carbonaceous aerosols, which are comprised of organic and elemental carbon [5,6].…”

Section: Introductionmentioning

confidence: 99%

Thermo-Optical and Particle Number Size Distribution Characteristics of Smoldering Smoke from Biomass Burning

Wang

Zhang

et al. 2019

Applied Sciences

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Controlled laboratory combustion experiments were conducted in the fire test room to mimic freshly emitted smoldering smoke of biomass burning in China. The biomass components were determined by ultimate analysis and proximate analysis before experiments. The particle number size distribution (PNSD) between 5 and 1000 nm of smoke was measured by a high sampling frequency size spectrometer. A cavity-enhanced aerosol albedometer with wavelength of 532 nm was used to measure scattering coefficients, extinction coefficients, and single scattering albedo (SSA) of smoldering smoke. The PNSDs of smoldering smoke from the burning of agricultural straw could be fitted with a bimodal lognormal distribution as modes around 10 nm (nucleation mode) and 60 nm (Aitken mode). The PNSDs of wood sawdust could be fitted with a trimodal lognormal distribution, while the two modes were in nucleation mode, and one was in Aitken mode. The bulk optical properties (scattering and extinction coefficients) of smoldering smoke had strong correlations with particle number concentrations of sizes bigger than 100 nm. The correlation between SSA and fixed carbon (FC) was strong (the correlation coefficient is 0.89), while the correlation between SSA and volatile matter (VM) or ash was weak. The relationship between SSA and N (or S) showed a positive correlation, while that of SSA and C showed a negative correlation. The relationship between SSA and VM/FC (or N) showed a strong linear relationship (r2 > 0.8). This paper could improve understanding of the relationship between the optical and particle size distribution properties of smoke from biomass burning and the components of biomass materials under similar combustion conditions.

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“…The size distribution and chemical constituents of aerosols determine their physicochemical properties, which correspond to their optical depth and toxicity. , Naturally, their compositions can be quite different because of their formation processes and specific sources. , Among these aerosols, carbonaceous particles in the atmosphere, which contribute a large portion of the overall mass load, play a major role in driving climate change. The effect of carbonaceous particles seems significant and even exceeds that of another global-warming gas, methane (CH 4 ). , Fine black carbon and organic carbon compounds, which originate from fossil fuel combustions, are usually called soot particles . Recently, brown carbon (BrC) has frequently appeared in the literature, referring to organic carbon that can efficiently absorb ultraviolet–visible light, although BrC is weaker in absorption over this wavelength range compared to black carbon .…”

Section: Introductionmentioning

confidence: 99%

Simulation of the Optical and Thermal Properties of Multiple Core–Shell Atmospheric Fractal Soot Agglomerates under Visible Solar Radiation

et al. 2019

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Soot is an important anthropogenic carbonaceous aerosol that forms atmospheric smog. The atmospheric presence of smog raises great concerns to human health. Soot also absorbs visible light from solar radiation, likely contributing to the climate change. This study focused on the optical and thermal effects of soot via a numerical simulation approach and included regular biomass, diesel, acetylene, and propane soot and three carbon surrogates for soot. To make the simulation more similar to real soot aerosols, two major submodels were integrated, which involved their core−shell structures and their fractal agglomerate structures. Four kinds of shell materials, including nonabsorbing (water, sulfuric acid, salt) and weak-absorbing (brown carbon) materials, were studied in their different shell thicknesses. The effects of the shell on the absorption enhancement of the bare soot particles and the dependence of absorption on the light wavelength were revealed. The brown carbon shell was found to exhibit greater absorption enhancement, and its absorption was doubled at 360 nm compared to that at 800 nm. Among the three soot aggregates from the different aging processes, the most stable embedding-type soot aggregate was found to have the maximum absorption of the incident light, resulting in an increase in the surrounding temperature by 0.35 K.

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Optical Properties, Chemical Composition and the Toxicological Potential of Urban Particulate Matter

Cited by 15 publications

References 51 publications

Assessing Ecotoxicity of Size-fractionated Airborne Particulate Matter

Assessing Ecotoxicity of Size-fractionated Airborne Particulate Matter

Thermo-Optical and Particle Number Size Distribution Characteristics of Smoldering Smoke from Biomass Burning

Simulation of the Optical and Thermal Properties of Multiple Core–Shell Atmospheric Fractal Soot Agglomerates under Visible Solar Radiation

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