Abstract
Biogenic volatile organic compounds (BVOCs) are subject to an intense emission by forests and crops into the atmosphere. They can rapidly react with the nitrate radical (NO3) during nighttime to form number of functionalized products. Among them, organic nitrates (ON) have been shown to behave as reservoirs of reactive nitrogen and consequently influence the ozone budget and secondary organic aerosols (SOA) which are known to have a direct and indirect effect on the radiative balance, and thus on climate. Nevertheless, BVOCs + NO3 reactions remain poorly understood. Thus, the primary purpose of the follow-up study is to furnish new kinetic and mechanistic data for one monoterpenes (C10H16), terpinolene, and one sesquiterpene (C15H24), β-caryophyllene, using simulation chamber experiments. These two compounds have been chosen in order to fill the lack of experimental data. Rate constants have been measured using both relative and absolute methods. They have been measured to be (5.5 ± 3.8) × 10−11 and (1.7 ± 1.4) × 10−11 cm3 molecule−1 s−1 for terpinolene and β-caryophyllene respectively. Mechanistic studies have also been conducted in order to identify and quantify the main reaction products. Total organic nitrates and SOA yields have been determined. Both terpenes appear to be major ON precursors both in gas and particle phase with formation yields of 69 % for terpinolene and 79 % for β-caryophyllene respectively. They also are major SOA precursor, with maximum SOA yields of around 60 % for both of the compounds. In order to support these observations, chemical analyses of the gas phase products were performed at the molecular scale using PTR-TOF-MS and FTIR. Detected products allowed proposing chemical mechanisms and providing explanations through peroxy and alkoxy reaction pathways.
Highlights
50 and β-caryophyllene, using simulation chambers for determining both rate constants and mechanisms, with an experimental protocol similar to the one used in Fouqueau et al, 2020a:
No mechanistic study has ever been published for terpinolene to our knowledge, whereas two studies were published for β-caryophyllene: SOA yield was measured by Jaoui et al, 2013 and the chemical composition of the aerosol phase was analyzed
This study shows that β-caryophyllene + NO3 is a major source of SOA, with a production yields estimated to 150%
Summary
The two different simulation chambers were used to study the reactions of terpinolene and β-caryophyllene with NO3 radicals: the CSA chamber and the CESAM chamber. To tackle the determination of these very fast reactions, a highly sensitive technique was requested for the monitoring of nitrate radicals. Absolute determinations were conducted using an in-situ incoherent broadband cavity-enhanced absorption spectroscopy (IBBCEAS), which was recently coupled with the CSA chamber (Fouqueau et al, 2020b). For both compounds, mechanistic studies have been conducted in CESAM chamber: total organic nitrate and SOA yields were determined and several individual gas phase products have been identified. Mechanisms have been proposed for the two compounds, using this information
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