Abstract. The reactions of a-pinene and of its main oxidation product, pinonaldehyde (3-acetyl-2,2-dimethyl-cyclobutyl-ethanal), with OH radicals have been studied in the laboratory using Fourier transform infrared spectroscopy for real-time monitoring of the gas-phase chemical species and a Scanning Mobility Particle Sizer system (3071 A, TSI) for the study of the secondary aerosol formation. All gas-phase molar yields were quantified using calibrated reference of the pure compound, except for the nitrates products. The results were: for the a-pinene experiments in the presence of NOx, pinonaldehyde, (87 _ 20)%; total nitrates (18 _+ 9)%; formaldehyde, (23 +_ 9)%; acetone (9 _ 6)%; for the a-pinene experiments in the absence of NOx: pinonaldehyde, (37 _+ 7)%; formaldehyde, (8 _ 1)%; acetone, (7 _+ 2)%; for the pinonaldehyde experiments in the presence of NO, formaldehyde (152 _ 56)% and acetone (15 _+ 7)%. The aerosol measurements showed that the condensed products accounted for the missing carbon in the gas-phase balance. The partitioning of the products into the condensed phase was found to be potentially .significant under experimental conditions but less than 10% for initial a-pinene concentrations lower than 1013 molecule cm -3 and hence negligible under atmospheric conditions in the absence of aerosol seeds. On the basis of these results a comprehensive mechanism for the gas-phase reaction of a-pinene with OH in the presence of NOx has been proposed, including quantitative values for all the involved branching ratios. al., 1998], have been studied in laboratory. These studies have generally focused on the first oxidation step and only a few products have been quantified. Pinonaldehyde (3-acetyl-2,2-dimethyl-cyclobutyl-ethanal) was found to be the main product but has never been quantified on an absolute basis by means of a calibrated sample of the pure compound. The only other reaction product identified and quantified is acetone. Moreover, most of the studies have not taken into account the condensed products formed by these reactions, which may represent a significant fraction of the carbon balance under laboratory conditions as it will be shown in the present work. As a result, the understanding of the mechanism for the reaction of a-pinene with OH radicals remained difficult. Furthermore, secondary oxidation steps such as the further reactions of pinonaldehyde, which are important to assess the overall effect of a-pinene on tropospheric chemistry, have never been studied.In the present work, the mechanism of the reaction of a-pinene with OH radicals has been studied. Several gas-phase products such as pinonaldehyde, alkyl nitrates, acetone, and formaldehyde, have been identified and, except for the alkyInitrates, quantified using calibrated reference samples. This work also gives a first insight into the oxidation mechanism beyond the initial oxidation step by studying the reaction of pinonaldehyde with OH radicals. A quantification of the condensed products formed in these reactions has been performe...
