Urban organic aerosol composition in Eastern China differs from North to South: Molecular insight from a liquid chromatography-Orbitrap mass spectrometry study

Wang, Kai; Huang, Ru‐Jin; Brüggemann, Martin; Yun, Zhang; Yang, Lü; Ni, Haiyan; Guo, Jie; Wang, Meng; Han, Jiajun; Bilde, Merete; Glasius, Marianne; Hoffmann, Thorsten

doi:10.5194/acp-2019-908

Cited by 5 publications

(6 citation statements)

References 53 publications

(120 reference statements)

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“…The dominance of aliphatic OS and NOS compounds is consistent with that observed in Figure 4. Similar results have been reported for several other cities in China, such as those in Changchun, Shanghai, and Guangzhou (Wang, Huang, et al., 2021), where the majority of OS compounds were aliphatics. The high abundance of aliphatic OSs in urban environments could be resulted from the interactions of substantial anthropogenic pollutants (e.g., SO 2 and sulfate particles) with biogenic precursors and the intermediate products (Glasius et al., 2018; Wei et al., 2020).…”

Section: Resultssupporting

confidence: 89%

Molecular Characteristics of Atmospheric Organosulfates During Summer and Winter Seasons in Two Cities of Southern and Northern China

Lin

Han

et al. 2022

JGR Atmospheres

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Organosulfates in atmospheric PM2.5 were investigated at two urban sites in Hefei and Shijiazhuang of southern and northern China during the summer and winter seasons of 2019–2020. Organic molecular composition was characterized using ultrahigh‐performance liquid chromatography coupled with Orbitrap mass spectrometry in negative electrospray ionization mode. There were overall 2,516–6,190 and 2,417–3,474 organic molecular formulas assigned on individual days in Hefei and Shijiazhuang, respectively, among which approximately 25%–41% were sulfur‐containing CHOS and CHONS compounds. The number of total organosulfates (including nitrooxy‐organosulfates) accounted for on average 84% and 79% of sulfur‐containing compounds during summer and winter in Shijiazhuang, which were much higher than those of 36% and 57% in Hefei. The higher fractions of organosulfates in the northern city of Shijiazhuang might be closely associated with the higher prevalence of SO2 and particulate sulfate. More than 96% in the peak areas of total organosulfates were present in aliphatic molecular structures instead of aromatics in both cities, suggesting the substantial contributions from biogenic precursors and anthropogenic long‐chain alkanes. The positive correlations (r: 0.33–0.96) of inorganic sulfate with the peak area abundance of organosulfates derived from isoprene and monoterpenes revealed the significant role of sulfate particles in the production of organosulfates. Particle acidity also correlated positively with these species during the winter in Hefei and summer in Shijiazhuang, yet negatively during other periods, indicating that additional reaction pathways would compete with acid‐catalyzed chemistry under atmospheric conditions limited by particle acidity or hydrocarbon precursors.

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Section: Resultssupporting

confidence: 89%

Molecular Characteristics of Atmospheric Organosulfates During Summer and Winter Seasons in Two Cities of Southern and Northern China

Lin

Han

et al. 2022

JGR Atmospheres

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“…The relative number of CHO-containing species found in our study is in good agreement with other studies measured in south China and Singapore [46,47]. Since we are able to detect and report other classes of compounds in addition to CHO compounds, such as large carbon fragments, inorganic compounds and PAHs, the relative proportion of CHO compounds is reduced compared to other studies [48]. If we count only organic compounds, the relative percentage of CHO-containing compounds rises to levels between 53 and 75%, as found in other studies [49].…”

Section: Number and Composition Of Compoundssupporting

confidence: 91%

Particle characterization and quantification of organic and inorganic compounds from Chinese and Iranian aerosol filter samples using scanning laser desorption/ionization mass spectrometry

2022

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Besides their influence on climate and cloud formation, many organic and inorganic substances in aerosol particles pose a risk to human health. Namely, polycyclic aromatic hydrocarbons (PAH) and heavy metals are suspected to be carcinogenic or acutely toxic. The detection and quantification of such compounds is difficult if only small amounts of particulate matter (PM) are available. In addition, filter samples are often complex and time-consuming to prepare for chromatographic measurements and elemental analysis. Here, we present a method based on high-resolution atmospheric pressure laser desorption ionization mass spectrometry imaging (AP-LDI-MSI) and statistical analysis which allows the analysis and characterization of very small sample quantities (< 30 µg) without any sample preparation. The power and simplicity of the method is demonstrated by two filter samples from heavily polluted mega cities. The samples were collected in Tehran (Iran) and Hangzhou (China) in February 2018. In the course of the measurement, more than 3200 sum formulae were assigned, which allowed a statistical evaluation of colocalized substances within the particles on the filter samples. This resulted in a classification of the different particle types on the filters. Finally, both megacities could be distinguished based on characteristic compounds. In the samples from Tehran, the number of sulphur-containing organic compounds was up to 6 times as high as the samples from Hangzhou, possibly due to the increasing efforts of the Chinese government to reduce sulphur emissions in recent years. Additionally, quantification of 13 PAH species was carried out via standard addition. Especially, the samples from Tehran showed elevated concentrations of PAHs, which in the case of higher-molecular-weight species (> m/z 228) were mostly more than twice as high as in Hangzhou. Both cities showed high levels of heavy metals and potentially harmful organic compounds, although their share of total particulate matter was significantly higher in the samples from Tehran. The pre-treatment of the samples was reduced to a minimum with this method, and only small amounts of particles were required to obtain a comprehensive picture for a specific filter sample. The described method provides faster and better control of air pollution in heavily polluted megacities. Graphical abstract

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“…The CHON+ and CHON– compounds were located in areas that corresponded to oxidized unsaturated compounds and intermediately oxidized organic compounds, respectively. The mean H/C and O/C ratios of the CHON+ and CHON– compounds were close to or slightly greater than the mean H/C and O/C ratios of the regional and rural sites of the Pearl River Delta (Jiang et al., 2020; Lin et al., 2012), as well as the mean H/C and O/C ratios of ambient aerosol samples collected in biomass burning potentially influenced sites and large cities such as Beijing (Jiang et al., 2016; Wang et al., 2018), Shanghai (Wang, Hayeck, et al., 2017), Changchun, and Mainz (Wang et al., 2018, 2021). However, the mean H/C and O/C ratios were significantly less than the mean H/C and O/C ratios of urban aged atmospheric aerosols collected from Cambridge, UK; California, USA.…”

Section: Resultsmentioning

confidence: 99%

“…However, the mean H/C and O/C ratios were significantly less than the mean H/C and O/C ratios of urban aged atmospheric aerosols collected from Cambridge, UK; California, USA. (O'Brien et al., 2014; Rincón et al., 2012; Willoughby et al., 2014); and Guangzhou on hazy days (Wang et al., 2021), as well as the aged atmospheric media of cloud water (Bianco et al., 2018; Zhao et al., 2013) and rainwater(Altieri et al., 2012). Furthermore, the degrees of oxidation and saturation of CHON compounds in Guangzhou were close to the degrees of oxidation and saturation of the BBOA samples (Cai et al., 2020; Song et al., 2018; Tang et al., 2020), vehicle emission, and tunnel aerosols (Tang et al., 2020), but significantly greater than the degrees of oxidation and saturation of fine particles from coal combustion (Song et al., 2018, 2019; Tang et al., 2020) and off‐road engine emissions (Cui et al., 2019).…”

Section: Resultsmentioning

confidence: 99%

Factors Influencing the Molecular Compositions and Distributions of Atmospheric Nitrogen‐Containing Compounds

et al. 2022

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NOCs deposition from atmospheric particles considerably affects the global nitrogen cycle and can have substantial effects on aquatic and terrestrial ecosystems (Altieri Abstract Atmospheric nitrogen-containing organic compounds (NOCs) are critical components of global nitrogen deposition and light-absorption species. The sources and compositions of NOCs are complex and remain largely unknown. Here, NOCs in 55 ambient aerosol samples collected in Guangzhou, South China, were analyzed via ultrahigh-resolution Fourier transform ion cyclotron resonance mass spectrometry in negative-ion and positive-ion electrospray ionization (ESI) modes. The molecular compositions of NOCs measured via ESI-and ESI+ exhibited considerable differences. NOCs detected in the negative mode were mainly composed of highly oxygenated organic nitrates (O/N = 6), whereas NOCs detected in the positive mode were mainly composed of reduced nitrogen-containing compounds (e.g., amides and amino acids). CHN compounds potentially corresponding to amines and alkaloids showed low abundance in the detection modes. Non-metric multidimensional scaling and individual compound correlation analyses showed that the molecular compositions of NOCs were mainly affected by anthropogenic activities and meteorological parameters. For example, anthropogenic activities such as biomass burning and secondary nitrogen-chemistry processes led to the accumulation of aromatic and highly oxygenated NOCs during winter. During summer, higher OH radical concentrations and temperatures will result in more prevalent or persistent reduced aliphatic NOCs, particularly lipid-like amines. Some variables (e.g., relative humidity) have distinct effects on the variation of different types of NOCs. More research is needed to reveal the influencing mechanisms. This study clarifies the molecular compositions of NOCs and the mechanisms by which various factors influence the molecular variations. The findings can guide the assessment of NOCs evolution and deposition.Plain Language Summary Negative and positive electrospray ionization coupled with Fourier transform ion cyclotron resonance mass spectrometry (ESI-FT-ICR-MS) was used to characterize the molecular composition of nitrogen-containing organic compounds (NOCs) from aerosol samples in Guangzhou. It was determined that a large amount of various NOCs are present in the samples, with NOCs in highly oxidative and reduced states can be roughly identified by distinct ionization modes. By combining the ESI-FT-ICR-MS results and statistical analysis, the factors that associated with the distribution of NOCs and how these factors worked were identified. Anthropogenic activities and meteorological parameters (e.g., temperature and oxidation levels) are the two important drivers that led to the variations of NOCs, resulting to inverse molecular patterns with different response to aromatic/highly unsaturated and saturated structures, respectively. This study provides a useful clue for studying NOCs in complex system, bridges the links between t...

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Urban organic aerosol composition in Eastern China differs from North to South: Molecular insight from a liquid chromatography-Orbitrap mass spectrometry study

Cited by 5 publications

References 53 publications

Molecular Characteristics of Atmospheric Organosulfates During Summer and Winter Seasons in Two Cities of Southern and Northern China

Molecular Characteristics of Atmospheric Organosulfates During Summer and Winter Seasons in Two Cities of Southern and Northern China

Particle characterization and quantification of organic and inorganic compounds from Chinese and Iranian aerosol filter samples using scanning laser desorption/ionization mass spectrometry

Factors Influencing the Molecular Compositions and Distributions of Atmospheric Nitrogen‐Containing Compounds

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