Development of a sensitive long path absorption photometer to quantify peroxides in aerosol particles (Peroxide-LOPAP)

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A new off-line instrument to quantify peroxides in aerosol particles using iodometry in long path absorption spectroscopy has been developed and is called peroxide long path absorption photometer (Peroxide-LOPAP). The new analytical setup features important technical innovations compared to hitherto published iodometric peroxide measurements. Firstly, the extraction, chemical conversion and measurement of the aerosol samples are performed in a closed oxygen-free (~ 1 ppb) environment. Secondly, a 50-cm optical detection cell is used for an increased photometric sensitivity. The limit of detection was 0.1 μM peroxide in solution or 0.25 nmol m⁻³ with respect to an aerosol sample volume of 1 m³. The test reaction was done at a constant elevated temperature of 40 °C and the reaction time was 60 min. <br><br> Calibration experiments showed that the test reaction with all reactive peroxides, i.e. hydrogen peroxide (H₂O₂), peracids and peroxides with vicinal carbonyl groups (e.g. lauroyl peroxide) goes to completion and their sensitivity (slope of calibration curve) varies by only &plusmn;5%. However, very inert peroxides have a lower sensitivity. For example, <i>tert</i>-butyl hydroperoxide shows only 37% sensitivity compared to H₂O₂ after 1 h. A kinetic study revealed that even after 5 h only 85% of this inert compound had reacted. <br><br> The time trends of the peroxide content in secondary organic aerosol (SOA) from the ozonolysis and photo-oxidation of &alpha;-pinene in smog chamber experiments were measured. The highest mass fraction of peroxides with 34% (assuming a molecular weight of 300 g mol^&minus;1) was found in freshly generated SOA from &alpha;-pinene ozonolysis. Mass fractions decreased with increasing NO levels in the photo-oxidation experiments. A decrease of the peroxide content was also observed with aging of the aerosol, indicating a decomposition of peroxides in the particles.