The CANOPEE project aims to better understand the biosphere–atmosphere exchanges of biogenic volatile organic compounds (BVOCs) in the case of Mediterranean ecosystems and the impact of in-canopy processes on the atmospheric chemical composition above the canopy. Based on an intensive field campaign, the objective of our work was to determine the chemical composition of the air inside a canopy as well as the net fluxes of reactive species between the canopy and the boundary layer. Measurements were carried out during spring 2012 at the field site of the Oak Observatory of the Observatoire de Haute Provence (O3HP) located in the southeast of France. The site is a forest ecosystem dominated by downy oak, Quercus pubescens Willd., a typical Mediterranean species which features large isoprene emission rates. Mixing ratios of isoprene, its degradation products methylvinylketone (MVK) and methacrolein (MACR) and several other oxygenated VOC (OxVOC) were measured above the canopy using an online proton transfer reaction mass spectrometer (PTR-MS), and fluxes were calculated by the disjunct eddy covariance approach. The O3HP site was found to be a very significant source of isoprene emissions, with daily maximum ambient concentrations ranging between 2–16 ppbv inside and 2–5 ppbv just above the top of the forest canopy. Significant isoprene fluxes were observed only during daytime, following diurnal cycles with midday net emission fluxes from the canopy ranging between 2.0 and 9.7 mg m?2 h1. Net isoprene normalized flux (at 30 °C, 1000 μmol quanta m?2 s1) was estimated at 7.4 mg m?2 h?1. Evidence of direct emission of methanol was also found exhibiting maximum daytime fluxes ranging between 0.2 and 0.6 mg m?2 h?1, whereas flux values for monoterpenes and others OxVOC such as acetone and acetaldehyde were below the detection limit. The MVK+MACR-to-isoprene ratio provided useful information on the oxidation of isoprene, and is in agreement with recent findings proposing weak production yields of MVK and MACR, in remote forest regions where the NOx concentrations are low. In-canopy chemical oxidation of isoprene was found to be weak and did not seem to have a significant impact on isoprene concentrations and fluxes above the canopy.
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机译:Canopee项目旨在更好地了解在地中海生态系统的情况下生物挥发性有机化合物(BVOC)的生物挥发性有机化合物(BVOC)的氛围以及在冠层上方大气化学成分上的影响。基于密集的野外活动,我们的作品的目的是确定树冠内的空气的化学成分以及树冠和边界层之间的反应物质的净助熔剂。 2012年春季现场进行了测量,位于法国东南部的Idippatoire de Haute Provence(O3HP)的橡木天文台的现场。该网站是森林生态系统,由柔软的橡树,昆士群岛,Quercus Pubescens Willd。,一种具有大型异戊二烯排放率的典型的地中海物种。异戊二烯的混合比例,其降解产物甲基乙烯基酮(MVK)和甲基丙酮蛋白(MACR)和几种其他含氧VOC(OXVOC)使用在线质子转移反应质谱仪(PTR-MS)上方测量冠层,并通过助熔剂计算分离涡流协方差方法。 O3HP部位被发现是异戊二烯排放的非常重要的来源,每日最大环境浓度范围为2-16ppbv,2-5 ppbv在森林树冠顶部上方。在白天期间仅观察到显着的异戊二烯通量,延长昼夜循环,午间净排放通量来自冠层的冠层,范围为2.0-9.7mg m?2 H1。净异戊二烯归一化通量(在30℃下,1000μmolQuanta m'2 s1)估计为7.4mgm≤2h≤1。还发现直接排放甲醇的证据表现出最大的白昼助熔剂,范围为0.2和0.6mg M 2 H 2 H 2 H 2 H 2,而单选物的助焊剂值和其他Oxvoc如丙酮和乙醛均低于检测限。 MVK + MACR-异戊二烯比提供有关异戊二烯氧化的有用信息,并与最近的结果一致,提出了NOx浓度低的远程林地区的MVK和MACR的弱产量。发现异戊二烯的冠层化学氧化是薄弱的,并且似乎对冠层上方的异戊二烯浓度和助熔剂没有显着影响。
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