Geosciences Division, Physical Research Laboratory, Ahmedabad 380009, India.
Geosciences Division, Physical Research Laboratory, Ahmedabad 380009, India.
Sci Total Environ. 2021 Nov 10;794:148589. doi: 10.1016/j.scitotenv.2021.148589. Epub 2021 Jun 25.
It is well established that light-absorbing organic aerosols (commonly known as brown carbon, BrC) impact climate. However, uncertainties remain as their contributions to absorption at different wavelengths are often ignored in climate models. Further, BrC exhibits differences in absorption at different wavelengths due to the variable composition including varying sources and meteorological conditions. However, diurnal variability in the spectral characteristics of water-soluble BrC (hereafter BrC) is not yet reported. This study presents unique measurement hitherto lacking in the literature. Online measurements of BrC were performed using an assembled system including a particle-into-liquid sampler, portable UV-Visible spectrophotometer with liquid waveguid capillary cell, and total carbon analyzer (PILS-LWCC-TOC). This system measured the absorption of ambient aerosol extracts at the wavelengths ranging from 300 to 600 nm with 2 min integration time and water-soluble organic carbon (WSOC) with 4 min integration time over a polluted megacity, New Delhi. Black carbon, carbon monoxide (CO), nitrogen oxides (NOx), and the chemical composition of non-refractory submicron aerosols were also measured in parallel. Diurnal variability in absorption coefficient (0.05 to 65 Mm), mass absorption efficiency (0.01 to 3.4 m gC) at 365 nm, and absorption angstrom exponent (AAE) of BrC for different wavelength range (AAE: 4.2-5.8; AAE: 5.5-8.0; and AAE: 5.3-7.3) is discussed. BrC chromophores absorbing at any wavelength showed minimum absorption during afternoon hours, suggesting the effects of boundary layer expansion and their photo-sensitive/volatile nature. On certain days, a considerable presence of BrC absorbing at 490 nm was observed during nighttime that disappears during the daytime. It appeared to be associated with secondary BrC. Observations also infer that BrC species emitted from the biomass and coal burning are more absorbing among all sources. A fraction of BrC is likely associated with trash burning, as inferred from the spectral characteristics of Factor-3 from the PMF analysis of BrC spectra. Such studies are essential in understanding the BrC characteristics and their further utilization in climate models.
已证实,光吸收性有机气溶胶(通常称为棕色碳,BrC)会对气候产生影响。然而,由于气候模型通常忽略了不同波长的吸收贡献,因此仍存在不确定性。此外,由于组成的变化,BrC 在不同波长处的吸收也存在差异,包括不同的来源和气象条件。然而,水溶性 BrC(以下简称 BrC)的光谱特征的日变化尚未有报道。本研究提供了迄今为止文献中缺乏的独特测量结果。使用包括粒子进液采样器、带有液体波导毛细管池的便携式紫外-可见分光光度计和总碳分析仪(PILS-LWCC-TOC)在内的组装系统进行了 BrC 的在线测量。该系统以 2 分钟的积分时间测量了从 300 到 600nm 波长范围内环境气溶胶提取物的吸收,以 4 分钟的积分时间测量了水溶性有机碳(WSOC),这是在一个污染严重的特大城市新德里进行的。同时还平行测量了黑碳、一氧化碳(CO)、氮氧化物(NOx)和非难挥发亚微米气溶胶的化学成分。讨论了 BrC 的吸收系数(0.05 到 65Mm)、365nm 处的质量吸收效率(0.01 到 3.4mgC)和不同波长范围的吸收消光系数(AAE)的日变化(AAE:4.2-5.8;AAE:5.5-8.0;AAE:5.3-7.3)。在任何波长处吸收的 BrC 发色团在下午时段的吸收最小,这表明了边界层扩展及其光敏感/易挥发性质的影响。在某些日子里,在夜间观察到相当数量的 490nm 处吸收的 BrC,而在白天则消失。这似乎与二次 BrC 有关。观测结果还推断,来自生物质和煤燃烧的 BrC 物种在所有来源中具有更高的吸收性。从 BrC 光谱的 PMF 分析中因子 3 的光谱特征推断,BrC 的一部分可能与垃圾燃烧有关。这些研究对于理解 BrC 的特征及其在气候模型中的进一步利用至关重要。
