TY - JOUR
T1 - Decomposition pathways of isoprene-derived hydrotrioxides and their clustering abilities in the atmosphere
AU - Ahongshangbam, Emelda
AU - Franzon, Lauri
AU - Almeida, Thomas G
AU - Hasan, Galib
AU - Frandsen, Benjamin N
AU - Myllys, Nanna
PY - 2025/2/21
Y1 - 2025/2/21
N2 - In atmospheric gas-phase chemistry, hydrotrioxides (ROOOH) are formed as intermediates in the reactions of peroxyl radicals (RO2) with OH radicals, and their stabilization has been confirmed experimentally by direct observation. In this study, we systematically investigated the probable decomposition pathways of isoprene-derived ROOOHs in the atmosphere. The kinetic analysis confirmed that the fast fragmentation of hydrotrioxides into their respective alkoxy radicals and hydroperoxyl radicals dominates over the other decomposition mechanisms. We also explored the decomposition of ROOOH proceeding via3(RO⋯HO2) product complexes, through which an intermolecular hydrogen transfer results in the formation of alcohol and molecular oxygen with a relatively low energy barrier. Furthermore, we studied the clustering abilities of hydrotrioxides with various types of atmospheric vapors, particularly acids and amines. The results indicate that the binding strength of these hydrotrioxides with other vapors is too low to drive clustering processes at ambient atmospheric concentrations, however, hydrotrioxides interact more strongly with bases and acid-base clusters than alcohols or hydroperoxides. These findings provide insight into the atmospheric stability and reactivity of hydrotrioxides, with implications for understanding their role in processes such as secondary organic aerosol formation.
AB - In atmospheric gas-phase chemistry, hydrotrioxides (ROOOH) are formed as intermediates in the reactions of peroxyl radicals (RO2) with OH radicals, and their stabilization has been confirmed experimentally by direct observation. In this study, we systematically investigated the probable decomposition pathways of isoprene-derived ROOOHs in the atmosphere. The kinetic analysis confirmed that the fast fragmentation of hydrotrioxides into their respective alkoxy radicals and hydroperoxyl radicals dominates over the other decomposition mechanisms. We also explored the decomposition of ROOOH proceeding via3(RO⋯HO2) product complexes, through which an intermolecular hydrogen transfer results in the formation of alcohol and molecular oxygen with a relatively low energy barrier. Furthermore, we studied the clustering abilities of hydrotrioxides with various types of atmospheric vapors, particularly acids and amines. The results indicate that the binding strength of these hydrotrioxides with other vapors is too low to drive clustering processes at ambient atmospheric concentrations, however, hydrotrioxides interact more strongly with bases and acid-base clusters than alcohols or hydroperoxides. These findings provide insight into the atmospheric stability and reactivity of hydrotrioxides, with implications for understanding their role in processes such as secondary organic aerosol formation.
UR - http://www.scopus.com/inward/record.url?scp=86000757757&partnerID=8YFLogxK
U2 - 10.1039/d4cp04329d
DO - 10.1039/d4cp04329d
M3 - Journal article
C2 - 40029036
SN - 1463-9076
VL - 27
SP - 5889
EP - 5901
JO - Physical chemistry chemical physics : PCCP
JF - Physical chemistry chemical physics : PCCP
IS - 11
ER -