Characteristics of volatile organic compounds, NO2, and effects on ozone formation at a site with high ozone level in Chengdu

Chengdu is a megacity in the southwest of China with high ozone (O₃) mixing ratio. Observation of volatile organic compounds (VOCs), NO₂ and O₃ with high temporal resolution was conducted in Chengdu to investigate the chemical processes and causes of high O₃ levels. The hourly mixing ratios of VOCs, NO₂, and O₃ were monitored by an online system from 28 August to 7 October, 2016. According to meteorological conditions, Chengdu, with relative warm weather and low wind speed, is favorable to O₃ formation. Part of the O₃ in Chengdu may be transported from the downtown area. In O₃ episodes, the average mixing ratios of NO₂ and O₃ were 20.20?ppbv and 47.95?ppbv, respectively. In non-O₃ episodes, the average mixing ratios of NO₂ and O₃ were 16.38?ppbv and 35.15?ppbv, respectively. The average mixing ratio of total VOCs (TVOCs) was 40.29?ppbv in non-O₃ episodes, which was lower than that in O₃ episodes (53.19?ppbv). Alkenes comprised 51.7% of the total O₃ formation potential (OFP) in Chengdu, followed by aromatics which accounted for 24.2%. Ethylene, trans-pentene, propene, and BTEX (benzene, ethylbenzene, toluene, m/p-xylene, o-xylene) were also major contributors to the OFP in Chengdu. In O₃ episodes, intensive secondary formations were observed during the campaign. Oxygenated VOCs (OVOCs), such as acetone, Methylethylketone (MEK), and Methylvinylketone (MVK) were abundant. Isoprene rapidly converted to MVK and Methacrolein (MACR) during O₃ episodes. Acetone was mainly the oxidant of C3-C5 hydrocarbons.     

沈阳工业区夏季VOCs组成特征及其对二次污染形成的贡献

利用2019年和2020年夏季沈阳市工业区大气挥发性有机物(VOCs)的观测数据,研究沈阳市夏季工业区大气VOCs的组成特征并初步判断其来源,并利用最大增量反应活性(MIR)和气溶胶生成系数(FAC)法分别估算该地大气VOCs的臭氧生成潜势(OFP)及二次有机气溶胶生成潜势(AFP).结果表明,观测期间沈阳市工业区ρ(总VOCs)平均值为41.66μg·m^-3,烷烃、烯烃、芳香烃和乙炔分别占总VOCs浓度的48.50%、 14.08%、 15.37%和22.05%.浓度排名前10的物种累计占总VOCs浓度的69.25%,其中大部分为C2～C5的烷烃,还包括乙炔、乙烯和部分芳香烃.总VOCs整体上呈现出早晚浓度高、中午浓度低的日变化特征,峰值分别出现在06:00和22:00,11:00～16:00处于较低水平.由甲苯/苯(T/B)和异戊烷/正戊烷的比值判断工业区主要受机动车尾气排放、溶剂使用、燃烧源和LPG/NG的影响.工业区大气VOCs的总AFP为41.43×10^-2μg·m^-3,其中芳香烃的贡献最大;总OFP贡献值为1...     

成都市工业挥发性有机物排源成分谱

选取成都市汽车制造和石油化工等典型工业行业,通过瓶采样和SUMMA罐采样及GC-MS分析方法,研究了不同生产工艺环节的挥发性有机物(VOCs)排放特征.结果表明,汽车制造各工艺环节均有各自的优势组分,其中喷漆排放以烷烃(32%)和芳香烃(35%)为主.家具制造排放特征与使用原辅料高度相关,以芳香烃(50%)和OVOCs(38%)为主.石油化工各装置区VOCs浓度范围为49～1 387μg·m~(-3),不同装置区存在较大差异,主要是由于炼油区主要产品为C_5～C_9的汽油和苯系物等,化工区则较多使用了溶剂同时生成烯烃类产品.电子制造均以OVOCs为主,占VOCs总排放的50%以上.制鞋行业排放VOCs主要由烷烃和OVOCs贡献,平均占比分别为52%和36%,与所用溶剂组分高度相关.汽车制造VOCs排放组分差异较大,主要以正十二烷和2-丁酮等为主.家具制造排放组分主要为苯乙烯、乙酸乙酯和间/对-二甲苯等,为涂料和稀释剂的典型组分.石油化工各装置区排放组分有差异,炼油区以苯乙烯等为主,化工区主要为1,3-丁二烯等,仓储区主要为C_3～C_5烷烃等,废水处理则主要为C_6～C_8烷烃等.电子制造主要组分均为乙醇和丙酮等醛酮组分.制鞋企业排放组分以C_5和C_6等烷烃为主.通过臭氧生成潜势计算比较,汽车制造和石油化工行业对臭氧生成潜势贡献较大的VOCs排放组分以烯烃和芳香烃为主,具有较高的污染源反应活性.研究表明各工业行业OVOCs排放比例(17%～96%)和对臭氧生成潜势贡献均较为显著,因此在进行VOCs排放控制时,除重点管控芳香烃和烯烃外,亦应提高对OVOCs组分的关注.     

Observation and analysis of atmospheric volatile organic compounds in a typical petrochemical area in Yangtze River Delta, China

Volatile organic compounds (VOCs) are a kind of important precursors for ozone photochemical formation. In this study, VOCs were measured from November 5th, 2013 to January 6th, 2014 at the Second Jinshan Industrial Area, Shanghai, China. The results showed that the measured VOCs were dominated by alkanes (41.8%), followed by aromatics (20.1%), alkenes (17.9%), and halo-hydrocarbons (12.5%). The daily trend of the VOC concentration showed a bimodal feature due to the rush-hour traffic in the morning and at nightfall. Based on the VOC concentration, a receptor model of Positive Matrix Factorization (PMF) coupled with the information related to VOC sources was applied to identify the major VOC emissions. The result showed five major VOC sources: solvent use and industrial processes were responsible for about 30% of the ambient VOCs, followed by rubber chemical industrial emissions (23%), refinery and petrochemical industrial emissions (21%), fuel evaporations (13%) and vehicular emissions (13%). The contribution of generalized industrial emissions was about 74% and significantly higher than that made by vehicle exhaust. Using a propylene-equivalent method, alkenes displayed the highest concentration, followed by aromatics and alkanes. Based on a maximum incremental reactivity (MIR) method, the average hourly ozone formation potential (OFP) of VOCs is 220.49?ppbv. The most significant source for ozone chemical formation was identified to be rubber chemical industrial emissions, following one by vehicular emission. The data shown herein may provide useful information to develop effective VOC pollution control strategies in industrialized area.     

成都市典型溶剂源使用行业VOCs排放成分特征

对成都市5类典型溶剂使用行业挥发性有机物(VOCs)进行采样监测,测定了其主要组成成分,得出了各行业的VOCs本地化排放系数.结果表明:芳香烃和含氧VOCs是主要成分,不同行业的特征VOCs组分各有不同;大气化学反应活性较大的物种大部分为芳香烃,其中对/间二甲苯的臭氧生成潜势(OFP)值约为141.88 mg·m~(-3),甲苯的OFP值约为90.90 mg·m~(-3),二者占总OFP的53%;家具制造行业的VOCs排放系数为0.61 kg·件~(-1),汽车喷涂行业VOCs排放系数为3.1 kg·辆~(-1),制鞋行业VOCs排放系数为4.04 g·双~(-1),印刷行业VOCs排放系数为34.7g·kg~(-1)油墨,人造板生产行业VOCs排放系数为3.67 g·m~(-3)人造板.     

生物质锅炉羰基化合物排放特征分析

为了探讨生物质锅炉羰基化合物的排放特征,采用气袋采样-PFPH衍生-GC/MS分析的方法测量了6台生物质锅炉排放烟气中的21种羰基化合物.结果表明,这些生物质锅炉的烟气中羰基化合物排放特征存在明显差异,总体而言,己醛和丙醛浓度在测定的21种目标化合物中比重最高,分别占总量的29%~47%和19%~31%,其次为甲醛和丙酮,乙醛和壬醛.通过羰基化合物排放量与消耗的燃料质量比值估算了排放因子,6台锅炉羰基化合物排放因子介于3.06~18.29mg/kg之间,平均为9.45±6.05mg/kg.采用最大增量反应活性法（MIR）评价了羰基化合物的化学反应活性及臭氧生成潜势（OFP）,平均总的臭氧生成潜势（以O₃计）为5.97gO₃/gVOCs;己醛、丙醛、甲醛对OFP的贡献尤为明显,丙酮虽然占有较高的质量浓度,但对OFP的贡献较低.     

青藏高原背景站大气VOCs浓度变化特征及来源分析

采用大气预浓缩与气象色谱/质谱联用法,对2013-09-13到2013-10-14期间在国家大气背景站青海门源站所采集的大气样品进行分析.结果显示,本次研究共检测出38种挥发性有机物(VOCs),其中烷烃16种,烯烃11种,芳香烃9种,卤代烃2种.从组成成分来看,烷烃所占比例最大,达58.6%,烯烃和芳香烃分别占29%和10.5%,卤代烃所占比例最小,仅为1.7%.观测期间大多数VOCs物种呈现白天浓度低、夜晚浓度高的变化趋势,具有明显的高原站点特性,但异戊烷、异戊二烯、甲苯则呈现相反趋势.采用臭氧生成潜势(OFP)对VOCs各组分活性进行分析,各类VOCs中烯烃对OFP贡献最大.利用主成分分析VOCs物种,提取出4个因子,分别归类于燃烧源、天然气和液化石油气的泄露、工业源、生物源.结合HYSPLIT 4.0后向轨迹模型,进一步确定气团的来源与运输途径,发现来自南向的污染源贡献是门源地区VOCs物种浓度增加的主要原因.     

柳州市春季大气挥发性有机物污染特征及源解析

为了解我国西南岩溶工业地区VOCs污染特征及其来源,2019年3月用GC955挥发性有机物在线监测系统对柳州市大气VOCs进行监测并对其污染特征、臭氧生成潜势（OFP）、气溶胶生成潜势（AFP）和正交矩阵因子模型（PMF）进行分析.结果表明：①研究区春季监测期间共检出50种VOCs组分,日平均摩尔分数为25.52×10^-9 mol·mol^-1.其中,烷烃、烯烃、炔烃及芳香烃分布占比为56.08%、19.63%、14.25%和10.04%.②VOCs摩尔分数呈现白天低,夜间高的特征.VOCs日变化中的峰值与早晚交通高峰出现的时间有一定的相关性,同时可能受到多方面因素的影响.③烯烃、芳香烃及烷烃对OFP贡献分布为44.30%、33.03%及19.96%,指示对于芳香烃和烯烃的控制应优先于烷烃.此外柳州市O₃生成处于VOCs敏感区,消减VOCs对O₃生成具有控制作用.④芳香烃对AFP的贡献高达95.27%,因此对于机动车尾气排放、溶剂的使用、汽车产业和化工产业这几个行业工艺上的改进及控制可同时有效地抑制臭氧及霾污染.⑤柳州春季VOCs排放源及其对总VOCs的贡献分别为：工业排放源（28.34%）、机动车源（25.47%）、燃烧源（24.37%）、溶剂使用源（13.28%）和植物排放源（8.54%）,表明控制工业排放源、机动车源和燃烧源是目前控制柳州市环境空气中VOCs污染的主要途径,同时,重点考虑控制这些排放源排放的烯烃和芳香烃.     

车用汽油及含氧燃料的环境效应

基于7辆国6轻型车的WLTC循环测试,计算了汽油?E10和MTBE10(汽油中添加10％体积的甲基叔丁基醚)排放的温室气体的致暖效应(GWP)、臭氧生成潜势(OFP)和非甲烷有机气体(NMOG)排放.结果表明,车队平均N2O和CH4排放的GWP分别为0.6和0.07g CO2e/km.E10和MTBE10的非CO2温室...     

珠江三角洲印刷行业VOCs组分排放清单及关键活性组分

根据珠江三角洲地区印刷行业活动数据和不锈钢罐采样-气质联用技术,获取了印刷工艺VOCs成分谱,建立了该地区2010年印刷行业VOCs组分排放清单,研究了不同工艺排放的臭氧生成潜势. 结果表明:该地区2010年印刷行业VOCs排放总量达8591.26t,深圳、东莞、佛山排放量较大.凹印是印刷行业主要VOCs排放工艺,排放量达5762.01t;平印和凸印次之,分别为1954.01和37.82t.不同工艺排放的VOCs组分差异较大,平印工艺排放的VOCs成分中异丙醇含量最多(306.58t),其次为正庚烷(115.87t);苯和甲苯是凸印工艺排放的VOCs成分中含量最大的2种化合物,分别达5.58和4.83t;乙酸乙酯是凹印工艺排放的VOCs成分中的首要化合物,达2482.85t.凸印工艺排放的VOCs单位浓度臭氧潜势最大,达1.30μg/m3,平印和凹印较小,分别为0.89和0.72μg/m3,各工艺排放的含氧有机物对臭氧生成潜势的贡献均为最大.