Laboratory of Atmospheric Chemistry, Paul Scherrer Institute, 5232 Villigen PSI, Switzerland.
Laboratory of Atmospheric Chemistry, Paul Scherrer Institute, 5232 Villigen PSI, Switzerland.
Sci Total Environ. 2020 Nov 10;742:140332. doi: 10.1016/j.scitotenv.2020.140332. Epub 2020 Jun 23.
Delhi, the capital of India, suffers from heavy local emissions as well as regional transport of air pollutants, resulting in severe aerosol loadings. To determine the sources of these pollutants, we have quantified the mass concentrations of 26 elements in airborne particles, measured by an online X-ray fluorescence spectrometer with time resolution between 30 min and 1 h. Measurements of PM and PM (particulate matter <10 μm and < 2.5 μm) were conducted during two consecutive winters (2018 and 2019) in Delhi. On average, 26 elements from Al to Pb made up ~25% and ~19% of the total PM mass (271 μg m and 300 μg m) in 2018 and 2019, respectively. Nine different aerosol sources were identified during both winters using positive matrix factorization (PMF), including dust, non-exhaust, an S-rich factor, two solid fuel combustion (SFC) factors and four industrial/combustion factors related to plume events (Cr-Ni-Mn, Cu-Cd-Pb, Pb-Sn-Se and Cl-Br-Se). All factors were resolved in both size ranges (but varying relative concentrations), comprising the following contributions to the elemental PM mass (in % average for 2018 and 2019): Cl-Br-Se (41.5%, 36.9%), dust (27.6%, 28.7%), non-exhaust (16.2%, 13.7%), S-rich (6.9%, 9.2%), SFC1 + SFC2 (4%, 7%), Pb-Sn-Se (2.3%, 1.66%), Cu-Cd-Pb (0.67%, 2.2%) and Cr-Ni-Mn (0.57%, 0.47%). Most of these sources had the highest relative contributions during late night (22:00 local time (LT)) and early morning hours (between 03:00 to 08:00 LT), which is consistent with enhanced emissions into a shallow boundary layer. Modelling of airmass source geography revealed that the Pb-Sn-Se, Cl-Br-Se and SFC2 factors prevailed for northwest winds (Pakistan, Punjab, Haryana and Delhi), while the Cu-Cd-Pb and S-rich factors originated from east (Nepal and Uttar Pradesh) and the Cr-Ni-Mn factor from northeast (Uttar Pradesh). In contrast, SFC1, dust and non-exhaust were not associated with any specific wind direction.
印度首都德里不仅受到本地排放物的影响,还受到区域空气污染物传输的影响,导致严重的气溶胶负荷。为了确定这些污染物的来源,我们使用在线 X 射线荧光光谱仪,以 30 分钟至 1 小时的时间分辨率,定量测量了空气中颗粒中 26 种元素的质量浓度。在德里连续两个冬季(2018 年和 2019 年)进行了 PM 和 PM(<10μm 和 <2.5μm 的颗粒物)测量。平均而言,2018 年和 2019 年,26 种从 Al 到 Pb 的元素分别占总 PM 质量的约 25%和 19%(271μg m 和 300μg m)。在两个冬季,使用正定矩阵因子分解(PMF)识别了 9 种不同的气溶胶源,包括灰尘、非排放物、富 S 因子、两个固体燃料燃烧(SFC)因子和与羽流事件相关的四个工业/燃烧因子(Cr-Ni-Mn、Cu-Cd-Pb、Pb-Sn-Se 和 Cl-Br-Se)。所有因子都在两个尺寸范围内得到解决(但相对浓度不同),它们对元素 PM 质量的贡献如下(2018 年和 2019 年平均占比):Cl-Br-Se(41.5%,36.9%)、灰尘(27.6%,28.7%)、非排放物(16.2%,13.7%)、富 S 因子(6.9%,9.2%)、SFC1+SFC2(4%,7%)、Pb-Sn-Se(2.3%,1.66%)、Cu-Cd-Pb(0.67%,2.2%)和 Cr-Ni-Mn(0.57%,0.47%)。这些源在当地时间(LT)22:00 至凌晨 03:00 至 08:00 之间的夜间和清晨时段的相对贡献最高,这与增强的浅层边界层排放一致。空气团源地理位置模型显示,Pb-Sn-Se、Cl-Br-Se 和 SFC2 因子盛行西北风(巴基斯坦、旁遮普邦、哈里亚纳邦和德里),而 Cu-Cd-Pb 和富 S 因子源自东方(尼泊尔和北方邦),Cr-Ni-Mn 因子源自东北(北方邦)。相比之下,SFC1、灰尘和非排放物与任何特定风向都没有关联。
