Abstract
Biogenic volatile organic compound (BVOC) emissions from six coniferous tree species, i.e. Pinus ponderosa (Ponderosa Pine), Picea pungens (Blue Spruce), Pseudotsuga menziesii (Rocky Mountain Douglas Fir) and Pinus longaeva (Bristlecone Pine), as well as from two deciduous species, Quercus gambelii (Gamble Oak) and Betula occidentalis (Western River Birch) were studied over a full annual growing cycle. Monoterpene (MT) and sesquiterpene (SQT) emissions rates were quantified in a total of 1236 individual branch enclosure samples. MT dominated coniferous emissions, producing greater than 95% of BVOC emissions. MT and SQT demonstrated short-term emission dependence with temperature. Two oxygenated MT, 1,8-cineol and piperitone, were both light and temperature dependent. Basal emission rates (BER, normalized to 1000μmolm−2s−1 and 30°C) were generally higher in spring and summer than in winter; MT seasonal BER from the coniferous trees maximized between 1.5 and 6.0μgg−1h−1, while seasonal lows were near 0.1μgg−1h−1. The fractional contribution of individual MT to total emissions was found to fluctuate with season. SQT BER measured from the coniferous trees ranged from <0.01 to 0.15μgg−1h−1. BER of up to 1.2μgg−1h−1 of the SQT germacrene B were found from Q. gambelii, peaking in late summer. The β-factor, used to define temperature dependence in emissions modeling, was not found to exhibit discernible growth season trends. A seasonal correction factor proposed by others in previous work to account for a sinusoidal shaped emission pattern was applied to the data. Varying levels of agreement were found between the data and model results for the different plant species seasonal data sets using this correction. Consequently, the analyses on this extensive data set suggest that it is not feasible to apply a universal seasonal correction factor across different vegetation species. A modeling exercise comparing two case scenarios, (1) without and (2) with consideration of the seasonal changes in emission factors illustrated large deviations when emission factors are applied for other seasons than those in which they were experimentally determined.
Highlights
Most vegetation emits an array of biogenic volatile organic compounds (BVOC)
This study investigates BVOC emission patterns utilizing light and temperature adjusted emission data sets with the goal of accounting for seasonal variation
MT were the dominant BVOC emitted from the four coniferous tree species studied
Summary
Most vegetation emits an array of biogenic volatile organic compounds (BVOC). BVOC are of interest to atmospheric scientists, among other fields, due to their chemical reactions once released into the atmosphere. Important products of BVOC oxidation include secondary organic aerosols (SOA) and ozone, both of which. D. Helmig et al / Chemosphere 93 (2013) 35–46 call for more phenologically based descriptors to accompany BVOC emission rate data sets, most emission data currently available are expressed solely by empirical light and temperature dependence algorithms (Duhl et al, 2008). Light and temperature based emission rate data sets are commonly normalized to standard light and temperature conditions, termed the basal emission rate (BER), which are used as input variables for atmospheric chemistry and transport models (Guenther et al, 1993)
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