Criegee intermediates (CIs) are a class of reactive radicals that are thought to play a key role in atmospheric chemistry through reactions with trace species that can lead to aerosol particle formation. Recent work has suggested that water vapor is likely to be the dominant sink for some CIs, although reactions with trace species that are sufficiently rapid can be locally competitive. Herein, we use broadband transient absorption spectroscopy to measure rate constants for the reactions of the simplest CI, CH2OO, with two inorganic acids, HCl and HNO3, both of which are present in polluted urban atmospheres. Both reactions are fast; at 295 K, the reactions of CH2OO with HCl and HNO3 have rate constants of 4.6×10−11 cm3 s−1 and 5.4×10−10 cm3 s−1, respectively. Complementary quantum‐chemical calculations show that these reactions form substituted hydroperoxides with no energy barrier. The results suggest that reactions of CIs with HNO3 in particular are likely to be competitive with those with water vapor in polluted urban areas under conditions of modest relative humidity.
Carbonyl oxides, or Criegee intermediates, are formed from the gas phase ozonolysis of alkenes and play a pivotal role in night-time and urban area atmospheric chemistry. Significant discrepancies exist among measurements of the strong B ̃(1)A'-X ̃(1)A' electronic transition of the simplest Criegee intermediate, CH2OO in the visible/near-UV. We report room temperature spectra of the B ̃(1)A'-X ̃(1)A' electronic absorption band of CH2OO acquired at higher resolution using both single-pass broadband absorption and cavity ring-down spectroscopy. The new absorption spectra confirm the vibrational structure on the red edge of the band that is absent from ionization depletion measurements. The absolute absorption cross sections over the 362-470 nm range are in good agreement with those reported by Ting et al. Broadband absorption spectra recorded over the temperature range of 276-357 K were identical within their mutual uncertainties, confirming that the vibrational structure is not due to hot bands.
Reactions of the simplest Criegee
intermediate (CH2OO)
with a series of alcohols have been studied in a flash photolysis
flow reactor. Laser photolysis of diiodomethane at 355 nm in the presence
of molecular oxygen was used to produce CH2OO, and the
absolute number densities were determined as a function of delay time
from analysis of broadband transient absorption spectra obtained using
a pulsed LED. The kinetics for the reactions of CH2OO with
methanol, ethanol, and 2-propanol were measured under pseudo-first-order
conditions at 295 K, yielding rate constants of (1.4 ± 0.4) ×
10–13 cm3 s–1, (2.3
± 0.6) × 10–13 cm3 s–1, and (1.9 ± 0.5) × 10–13 cm3 s–1, respectively. Complementary ab initio calculations
were performed at the CCSD(T)/aug-cc-pVTZ//CCSD/cc-pVDZ level of theory
to characterize stationary points on the reaction enthalpy and free
energy surfaces and to elucidate the thermochemistry and mechanisms.
The reactions proceed over free energy barriers of ∼8 kcal
mol–1 to form geminal alkoxymethyl hydroperoxides:
methoxymethyl hydroperoxide (MMHP), ethoxymethyl hydroperoxide (EMHP),
and isopropoxymethyl hydroperoxide (PMHP). The experimental and theoretical
results are compared to reactions of CH2OO with other hydroxylic
compounds, such as water and carboxylic acids, and trends in reactivity
are discussed.
Criegee intermediates (CIs) are a class of reactive radicals that are thought to play a key role in atmospheric chemistry through reactions with trace species that can lead to aerosol particle formation. Recent work has suggested that water vapor is likely to be the dominant sink for some CIs, although reactions with trace species that are sufficiently rapid can be locally competitive. Herein, we use broadband transient absorption spectroscopy to measure rate constants for the reactions of the simplest CI, CH2OO, with two inorganic acids, HCl and HNO3, both of which are present in polluted urban atmospheres. Both reactions are fast; at 295 K, the reactions of CH2OO with HCl and HNO3 have rate constants of 4.6×10−11 cm3 s−1 and 5.4×10−10 cm3 s−1, respectively. Complementary quantum‐chemical calculations show that these reactions form substituted hydroperoxides with no energy barrier. The results suggest that reactions of CIs with HNO3 in particular are likely to be competitive with those with water vapor in polluted urban areas under conditions of modest relative humidity.
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