Microphysical properties of atmospheric soot and organic particles: measurements, modeling, and impacts

Atmospheric soot and organic particles from fossil fuel combustion and biomass burning modify Earth’s climate through their interactions with solar radiation and through modifications of cloud properties by acting as cloud condensation nuclei and ice nucleating particles. Recent advancements in unde...

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Bibliographic Details
Published in:NPJ climate and atmospheric science 2024-03, Vol.7 (1), p.65-14, Article 65
Main Authors: Li, Weijun, Riemer, Nicole, Xu, Liang, Wang, Yuanyuan, Adachi, Kouji, Shi, Zongbo, Zhang, Daizhou, Zheng, Zhonghua, Laskin, Alexander
Format: Article
Language:English
Subjects:
704/106/35/824
704/172/169/824
704/172/4081
Aging
atmospheric chemistry
Atmospheric models
atmospheric organic particles
Atmospheric Protection/Air Quality Control/Air Pollution
Atmospheric Sciences
Biomass burning
Climate Change/Climate Change Impacts
Climate effects
Climatology
Composition
Condensation nuclei
Core-shell structure
Earth and Environmental Science
Earth Sciences
Electromagnetic absorption
environmental impact
ENVIRONMENTAL SCIENCES
Fossil fuels
Fractal geometry
Fuel combustion
Heterogeneity
light absorption
Liquid phases
Morphology
Optical properties
Organic constituents
Phase separation
Radiative forcing
Review Article
Solar radiation
Soot
Tar balls
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Summary:Atmospheric soot and organic particles from fossil fuel combustion and biomass burning modify Earth’s climate through their interactions with solar radiation and through modifications of cloud properties by acting as cloud condensation nuclei and ice nucleating particles. Recent advancements in understanding their individual properties and microscopic composition have led to heightened interest in their microphysical properties. This review article provides an overview of current advanced microscopic measurements and offers insights into future avenues for studying microphysical properties of these particles. To quantify soot morphology and ageing, fractal dimension ( D f ) is a commonly employed quantitative metric which allows to characterize morphologies of soot aggregates and their modifications in relation to ageing factors like internal mixing state, core-shell structures, phase, and composition heterogeneity. Models have been developed to incorporate D f and mixing diversity metrics of aged soot particles, enabling quantitative assessment of their optical absorption and radiative forcing effects. The microphysical properties of soot and organic particles are complex and they are influenced by particle sources, ageing process, and meteorological conditions. Furthermore, soluble organic particles exhibit diverse forms and can engage in liquid–liquid phase separation with sulfate and nitrate components. Primary carbonaceous particles such as tar balls and soot warrant further attention due to their strong light absorbing properties, presence of toxic organic constituents, and small size, which can impact human health. Future research needs include both atmospheric measurements and modeling approaches, focusing on changes in the mixing structures of soot and organic particle ensembles, their effects on climate dynamics and human health.
ISSN:2397-3722
2397-3722
DOI:10.1038/s41612-024-00610-8