Abstract. Highly oxygenated organic molecules (HOMs) are important contributors
to secondary organic aerosol (SOA) and new-particle formation (NPF) in the
boreal atmosphere. This newly discovered class of molecules is efficiently
formed from atmospheric oxidation of biogenic volatile organic compounds
(VOCs), such as monoterpenes, through a process called autoxidation. This
process, in which peroxy-radical intermediates isomerize to allow addition of
molecular oxygen, is expected to be highly temperature-dependent. Here, we
studied the dynamics of HOM formation during α-pinene ozonolysis
experiments performed at three different temperatures, 20, 0 and
−15 ∘C, in the Aarhus University Research on Aerosol (AURA)
chamber. We found that the HOM formation, under our experimental conditions
(50 ppb α-pinene and 100 ppb ozone), decreased considerably at
lower temperature, with molar yields dropping by around a factor of 50
when experiments were performed at 0 ∘C, compared to 20 ∘C.
At −15 ∘C, the HOM signals were already close to the detection
limit of the nitrate-based chemical ionization atmospheric pressure interface
time-of-flight (CI-APi-TOF) mass spectrometer used for measuring gas-phase
HOMs. Surprisingly, comparing spectra measured at 0 and 20 ∘C,
ratios between HOMs of different oxidation levels, e.g., the typical HOM
products C10H14O7, C10H14O9, and
C10H14O11, changed considerably less than the total HOM
yields. More oxidized species have undergone more isomerization steps;
yet, at lower temperature, they did not decrease more than the less oxidized
species. One possible explanation is that the primary rate-limiting steps
forming these HOMs occur before the products become oxygenated enough to be
detected by our CI-APi-TOF (i.e., typically seven or more oxygen atoms). The
strong temperature dependence of HOM formation was observed under
temperatures highly relevant to the boreal forest, but the exact magnitude
of this effect in the atmosphere will be much more complex: the fate of
peroxy radicals is a competition between autoxidation (influenced by
temperature and VOC type) and bimolecular termination pathways (influenced
mainly by concentration of reaction partners). While the temperature
influence is likely smaller in the boreal atmosphere than in our chamber, both the
magnitude and complexity of this effect clearly deserve more consideration
in future studies in order to estimate the ultimate role of HOMs on SOA and
NPF under different atmospheric conditions.
