Spherical tarball particles form through rapid chemical and physical changes of organic matter in biomass-burning smoke.
Kouji AdachiArthur J SedlacekLawrence KleinmanStephen R SpringstonJian WangDuli ChandJohn M HubbeJohn E ShillingTimothy B OnaschTakeshi KinaseKohei SakataYoshio TakahashiPeter R BuseckPublished in: Proceedings of the National Academy of Sciences of the United States of America (2019)
Biomass burning (BB) emits enormous amounts of aerosol particles and gases into the atmosphere and thereby significantly influences regional air quality and global climate. A dominant particle type from BB is spherical organic aerosol particles commonly referred to as tarballs. Currently, tarballs can only be identified, using microscopy, from their uniquely spherical shapes following impaction onto a grid. Despite their abundance and potential significance for climate, many unanswered questions related to their formation, emission inventory, removal processes, and optical properties still remain. Here, we report analysis that supports tarball formation in which primary organic particles undergo chemical and physical processing within ∼3 h of emission. Transmission electron microscopy analysis reveals that the number fractions of tarballs and the ratios of N and O relative to K, the latter a conserved tracer, increase with particle age and that the more-spherical particles on the substrates had higher ratios of N and O relative to K. Scanning transmission X-ray spectrometry and electron energy loss spectrometry analyses show that these chemical changes are accompanied by the formation of organic compounds that contain nitrogen and carboxylic acid. The results imply that the chemical changes increase the particle sphericity on the substrates, which correlates with particle surface tension and viscosity, and contribute to tarball formation during aging in BB smoke. These findings will enable models to better partition tarball contributions to BB radiative forcing and, in so doing, better help constrain radiative forcing models of BB events.
Keyphrases
- electron microscopy
- growth factor
- high resolution
- recombinant human
- water soluble
- climate change
- organic matter
- physical activity
- wastewater treatment
- mental health
- transcription factor
- magnetic resonance imaging
- risk assessment
- single molecule
- computed tomography
- high throughput
- high speed
- human health
- magnetic resonance
- antibiotic resistance genes
- loop mediated isothermal amplification
- pet imaging