Particle Inception from Gas Phase Reactions

The physical chemistry that enables particles to form and grow from gas phase precursors is highly complex and spans systems from the highly oxygenated particles of secondary organic aerosol to the carbonaceous particles of combustion, i.e., soot. At the CRF, scientists apply advanced mass spectrometric methods to probe the gas phase chemistry of polycyclic aromatic hydrocarbons (PAH)  formation in the high-temperature environment of flames and to study the chain of reactions that lead to highly oxygenated molecules at atmospherically relevant temperatures.

Understanding soot inception requires a chemical mechanism that can covalently bond hydrocarbon precursors at high temperatures rapidly enough to explain particle formation. CRF researchers, in collaboration with Lawrence Berkeley National Laboratory and University of California–Berkeley, highlighted the possibility of clustering of hydrocarbons by radical-chain reactions (CHRCR) driven by resonance-stabilized hydrocarbon radicals. CRF scientists employed tandem mass spectrometry to identify aliphatically bridged polycyclic aromatic hydrocarbons and PAHs with aliphatic side chains, which have been hypothesized to serve as “seeds” for soot particles. Current work at the CRF links controlled experimental kinetics investigations, machine learning methods, and automated theoretical kinetics to understand the role of resonance stabilization in the clustering reactions that lead to soot.

The formation and growth of atmospheric aerosols, important for climate and Earth’s radiation balance, is linked to low-volatility, highly oxygenated molecules (HOM) from gas phase oxidation of hydrocarbons. CRF researchers have investigated the production of HOM via sequential reactions of Criegee intermediates from ozonolysis and multiple additions to molecular oxygen in peroxy-radical driven chemistry. These oxidation processes form a bridge between the high-temperature oxidation important in ignition and combustion and the lower-temperature conditions of tropospheric chemistry.

The yellow color at the top of the flame comes from the glow of hot soot. The diagram (upper right) depicts some possible reactions that can grow molecules large enough to lead to the formation of the initial particles that start soot growth in the flame. Source: https://doi.org/10.1021/acs.jpca.8b08947
The yellow color at the top of the flame comes from the glow of hot soot. The diagram (upper right) depicts some possible reactions that can grow molecules large enough to lead to the formation of the initial particles that start soot growth in the flame. Source: https://doi.org/10.1021/acs.jpca.8b08947
Potential energy diagram for a reaction sequence, driven by resonance-stabilized radical (RSR) formation, that is representative of the CHRCR mechanism. Source: https://science.sciencemag.org/content/361/6406/997
Potential energy diagram for a reaction sequence, driven by resonance-stabilized radical (RSR) formation, that is representative of the CHRCR mechanism. Source: https://science.sciencemag.org/content/361/6406/997
CRF researchers (left to right) Scott Skeen (now at Dixie State University), Nils Hansen, and postdoc Brian Adamson (now at ThermoFisher) around the tandem mass spectrometer they used to study the structure of large hydrocarbon molecules in a sooting flame. (Photo credit: Michael Padilla)
CRF researchers (left to right) Scott Skeen (now at Dixie State University), Nils Hansen, and postdoc Brian Adamson (now at ThermoFisher) around the tandem mass spectrometer they used to study the structure of large hydrocarbon molecules in a sooting flame. (Photo credit: Michael Padilla)

Key Contributions

Partners

  • Hope Michelsen (University of Colorado)
  • Kevin Wilson (Lawrence Berkeley National Laboratory)
  • Ralf Kaiser (University of Hawaii)
  • Yiguang Ju (Princeton University)

PIs: Nils Hansen, Habib Najm, Craig A. Taatjes, Judit Zádor