the Creative Commons Attribution 4.0 License.
the Creative Commons Attribution 4.0 License.
Measurement report: Formation of tropospheric brown carbon in a lifting air mass
Can Wu
Xiaodi Liu
Ke Zhang
Si Zhang
Jianjun Li
Rui Li
Fan Zhang
An enhanced formation of brown carbon (BrC) with a non-negligible warming effect at the tropopause has recently been found. However, its formation mechanism is unclear. Here, we report on a BrC formation process that happens during air mass upward transport by conducting simultaneous measurements on atmospheric BrC with a 4 h time resolution at the mountain foot (MF, 400 m a.s.l.) and mountainside (MS, 1120 m a.s.l.) of Mt. Hua, China, in the 2016 summer. Our results showed that the daytime light absorption (abs365 nm) of BrC on the MS is approximately 60 % lower than that at the MF due to a dilution effect caused by the planetary boundary layer expansion, but the daytime light absorption of BrC relative to black carbon on the MS is about 30 % higher than that at the MF, suggesting a significant formation of secondary BrC in the lifting process of air mass from the MF to the MS. Such a secondary formation accounted for > 50 % of BrC on the MS but only 27 % of BrC at the MF. Moreover, the N:C elemental ratio of the daytime BrC was 15 % higher on the MS than that at the MF, mainly due to an aerosol aqueous-phase formation of water-soluble organic nitrogen (WSON) compounds. Stable nitrogen isotope composition further indicated that such light-absorbing WSON compounds were produced from the aerosol aqueous-phase reaction of carbonyls with NH. Our work revealed, for the first time, that ammonia-induced aerosol aqueous reactions can significantly promote BrC formation during the air mass lifting process, which is probably responsible for an enhanced light absorption of BrC in the upper boundary layer.
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Light-absorbing organic aerosols, known as brown carbon (BrC), can efficiently absorb solar radiation in the visible to near-ultraviolet (UV) wavelength range (Laskin et al., 2015; D. Liu et al., 2020; Chakrabarty et al., 2023), which corresponds to 27 %–70 % of black carbon (BC) light absorption in the lower troposphere (Saleh et al., 2015; Lin et al., 2014, 2015), suggesting that BrC can substantially perturb the planetary radiation budget (Qian et al., 2015; Lin et al., 2014; Liu et al., 2015). By absorbing solar radiation at short wavelengths, BrC can strongly alter local gas-phase photochemistry and atmospheric oxidation through decreasing the photolysis rates of OH radicals, NO2, and O3, leading to a reduction in atmospheric oxidant concentration of up to ∼ 30 % (Hammer et al., 2016; Gligorovski et al., 2015; Jo et al., 2016). BrC in the atmosphere also acts as a photosensitizer and produces active intermediates; thus, it can promote sulfate formation (Y. Liu et al., 2020b). In addition, BrC comprises numerous organic species and can induce adverse human health effects because some of the chromophores are toxic (Huang et al., 2018; Hsu et al., 2014; Yan et al., 2018).
Atmospheric BrC has both primary and secondary sources. Biomass burning is believed to be the major source of primary BrC (Chakrabarty et al., 2023), while emissions from fossil fuel combustion are also an important source of primary BrC in the urban atmosphere (Yan et al., 2017; Corbin et al., 2019), which accounts for even more than 40 % of the total BrC in the heating season (Li et al., 2023). In the past decades, numerous studies have reported that BrC can also be secondarily generated in the atmosphere, such as through the photooxidation of aromatics under high NOx conditions (Lin et al., 2015; Liu et al., 2021), through NH-initiated reactions with atmospherically relevant carbonyls (Y. Li et al., 2021; Kampf et al., 2012; Laskin et al., 2014; Z. Li et al., 2019), and through radical oxidations of various volatile organic compounds (VOCs) (Sumlin et al., 2017; Gelencser et al., 2003; Lu et al., 2011). BrC is chemically active, which means it may undergo photobleaching (Schnitzler et al., 2022; Gilardoni et al., 2016), posing significant challenges for characterizing BrC molecular composition and its links to optical properties.
Recently, aircraft measurements conduced over the continental United States observed an enhanced short-wavelength optical absorption of BrC relative to BC at altitudes between 5 and 12 km (Zhang et al., 2017), indicating that secondary formation is one of the crucial sources of such high-altitude BrC. Numerical model studies reported that global radiative forcing caused by BrC ranges from 0.1 to 0.6 W m−2 (Zhang et al., 2020; Lin et al., 2014; Drugé et al., 2022), suggesting a non-negligible impact of BrC on global climate change. Studies found that such climate effects are highly sensitive to BrC and that the sensitivity rapidly increases with an increase in altitude (Zhang et al., 2017; Nazarenko et al., 2017; Hodnebrog et al., 2014). The abundant BrC at the tropopause would bring about prominent impacts on radiative forcing, which could even be twice the magnitude of that induced by low-altitude BrC (Zhang et al., 2017). Due to the limited number of field observations, however, the vertical distribution and formation mechanism of tropospheric BrC are still unclear, especially in the upper troposphere, where the direct radiative forcing of BrC is much stronger than that in the ground surface atmosphere.
To elucidate the formation mechanism of BrC in the troposphere, synchronous observations on atmospheric BrC were conducted on the mountainside and at the mountain foot of Mt. Hua, which is located close to the Guanzhong basin, one of the areas with the heaviest PM2.5 pollution in China owing to the intensive activities of fossil fuel combustion and the unfavorable topography (Q. Wang et al., 2022; Wu et al., 2020; Wang et al., 2011, 2016). Our previous study has shown that inorganic aerosol chemistry in the atmosphere over Mt. Hua is dominated by the air mass transport from the Guanzhong basin ground surface, in which (NH4)2SO4 is continuously produced during the air mass lifting process, along with a decrease in aerosol acidity (Wu et al., 2022). Here, we investigated the formation mechanism of secondary BrC during the lifting process of air masses from the Guanzhong basin to the mountainous atmosphere of Mt. Hua. We firstly discussed the differences in the vertical distribution and optical absorption of water-soluble BrC between the ground surface and the mountainous atmosphere, and then we explored their formation mechanisms in the upper boundary layer. To the best of our knowledge, we found for the first time that ammonia-induced aerosol aqueous-phase reactions with carbonyls are the dominant formation pathway of BrC in the air mass lifting process, which is responsible for the high ratio of BrC to BC in the top troposphere.
2.1 Sample collection
Offline PM2.5 samples with a 4 h interval were synchronously collected onto prebaked quartz filters (at 450° for 6 h) at two locations of Mt. Hua from 27 August to 17 September 2016. One sampling site is located at the mountain foot (MF – 34°32 N, 110°5 E; 400 m a.s.l.), and another one is situated on the mountainside (MS – 34°29 N, 110°3 E; 1120 m a.s.l.) with little anthropogenic activity due to the steep terrain of the mountain region. The horizontal distance between the two sites is ∼ 8 km, and the vertical distance is about 1 km (Fig. S1 in the Supplement). As revealed in our previous study (Wu et al., 2022), vertical divergence simulated by the WRF-Chem model decreased gradually as elevation increased, along with the prevailing southerly winds, indicating the feasibility of vertical transport of air parcels from the MF to the MS. Additionally, we also note that the change in emission sources between two sites was insignificant in a lifting air mass, as indicated by the indistinctive divergences of diagnostic ratios and the proportion of organic tracers from emission sources. Such conditions can avoid the interferences caused by the emission source changes when exploring the aging process of BrC. More descriptions on the two sites have been documented in our previous study, along with the details on the sampling instrument setup (Wu et al., 2022). Mass concentrations of PM2.5, NO2, and O3 at the MS site were directly quantified by E-BAM (Met One Instruments, USA) and NOx and O3 analyzers (Thermo, Model 42i, USA; Thermo, Model 49i, USA), respectively. At the MF site, the data of the above species, apart from PM2.5, monitored by another E-BAM, were downloaded from the Weinan Ecological Environment Bureau (http://sthjj.weinan.gov.cn/, last access: 8 July 2021). Meteorological parameters of both sampling sites were downloaded from the Shaanxi Meteorological Bureau website (http://sn.cma.gov.cn/, last access: 8 July 2021).
2.2 Chemical analysis
The organic carbon (OC) and elemental carbon (EC) of PM2.5 filter samples were quantified by a DRI Model 2001 Thermal–Optical Carbon Analyzer following the IMPROVE-A temperature protocol (Chow et al., 2007). Water-soluble organic carbon (WSOC) and water-soluble total nitrogen (WSTN) of PM2.5 were extracted using Milli-Q pure water (18.2 MΩ) and were determined using a total organic carbon (TOC) analyzer (Model TOC-L CPH, Shimadzu, Japan). Water-soluble organic nitrogen (WSON) is calculated by deducting the water-soluble inorganic nitrogen (WSIN) from WSTN (i.e., WSON=WSTN−WSIN). Molecular compositions (e.g., nitrophenols, polycyclic aromatic hydrocarbons – PAHs –, and other organic tracers) in the PM2.5 filter samples were quantified by gas chromatography (HP 7890A, Agilent Co., USA) coupled with a mass spectroscopy detector (GC/MS) (HP 5975, Agilent Co., USA) after the sample extraction and derivatization. The details of the extraction and derivatization can be found elsewhere (Li et al., 2023, 2020; Wang et al., 2006). Briefly, one-fourth of the filter sample was extracted with a mixture of methanol and dichloromethane (2:1, ). Then the extracts were derivatized with N,O-bis-(trimethylsilyl) trifluoroacetamide (BSTFA).
The stable nitrogen isotope compositions of NH (δ15N–NH) were determined by the isotopic analysis of nitrous oxide (N2O) derived from the chemical conversion of NH and were finally quantified by a PreCon–GasBench–IRMS system. This is a reliable method for nitrogen isotope analysis of the sample with a low NH concentration, the precision of which can be up to 0.2 ‰. More details regarding the analytical artifact and quality-controlling protocols can be found in our previous studies. Furthermore, only the daytime samples were analyzed for the δ15N–NH here, and a merging pretreatment was applied for the daily samples to meet the analysis requirements.
Additionally, a high-resolution time-of-flight aerosol mass spectrometer (Aerodyne Research Inc., Billerica, MA, USA) was employed to determine the chemical compositions of water-soluble organic matter (WSOM) in PM2.5, the method of which is similar to that reported by Daellenbach et al. (2016). The offline analytical procedure has been reported previously; here, we only give a brief description (Ge et al., 2017; Sun et al., 2011). One-eighth of the PM2.5 filter samples were extracted with pure water. Then, the water extracts were atomized using argon as the carrier gas, dried by a diffusion drier, and ultimately quantified by the aerosol mass spectrometer. Purified water was also treated in the same manner prior to each sample running, which was deemed to be an analytical blank. As we mainly focused on the WSOM chemical composition, a deep post-processing was conducted for the V-mode data in this study using the Igor-based Aerosol Mass Spectrometer Analysis Toolkit. Element ratios of WSOM, including ratios of oxygen to carbon (), hydrogen to carbon (), nitrogen to carbon (), and organic mass to organic carbon (OM/OC), were determined according to the improved Aitken (I-A) method (Canagaratna et al., 2015). The mass load of WSOM in ambient air can be accurately estimated using Eq. (1) since the chemical species concentration in atomized aerosols depends on the flow rate of the carrier gas and extract concentration.
In the above, WSOM is water-soluble organic matter (WSOM) in the atmosphere (µg m−3); WSOC is water-soluble organic carbon (WSOC, µgC m−3) in the atmosphere, measured by the TOC analyzer; and OM/OCWSOM is the mass ratio of WSOM and OC, determined by the aerosol mass spectrometer. To obtain reliable data, the ionization efficiencies of HR-AMS were calibrated with 300 nm (Dm) ammonium nitrate and ammonium sulfate particles following the standard protocols (Sun et al., 2020; Jayne et al., 2000); furthermore, the relative ionization efficiencies (RIEs) of 4.1 and 0.8 were used for ammonium and sulfate, while the default RIEs were applied for organics, nitrate, and chloride.
2.3 Optical absorption of BrC
Measurements of the UV–Vis absorption spectra of water-soluble BrC in PM2.5 were performed using a liquid waveguide capillary UV–Vis spectrometer with a long effective path length (1 m). The extracted solutions of BrC were prepared using a similar treatment to that used for WSOC (Sect. S1), the absorption spectra of which were converted into the absorption coefficient at a given wavelength λ (absλ, M m−1, Eq. S1). The mass absorption efficiency (MAEλ, m2 gC−1) corresponding to water-soluble BrC at a given wavelength λ can be calculated as follows:
where M (µgC m−3) is the mass concentration for water-soluble organic carbon (WSOC). The absorption Ångström exponent (AAE) indicates the spectral dependence of a species, which was quantified by a linear regression of log (absλ) versus log (λ) over a wavelength rang of 300–500 nm (Wu et al., 2020).
2.4 Positive matrix factorization (PMF) source apportionment
To quantitatively determine the fractional contribution of specific sources to BrC, a positive matrix factorization (PMF) receptor model (EPA PMF 5.0 version) coupled with a bootstrap technique was applied here, the principles of which have been documented in previous studies (Brinkman et al., 2006; Paatero and Tapper, 1994). Briefly, WSOC, WSON, SO, NH, Mg2+, Ca2+, abs365 nm, and organic tracers (BbF, BghiP, and levo.) are the input variables in the present work, all of which are regarded to be strong variables, expect for BghiP, with a low ratio (0.6). Another input dataset is the uncertainty matrix that is calculated according to the equations outlined below (Eq. 3). The uncertainties of each factor profile are also evaluated by a bootstrap analysis, the results of which showed that the reproducibility of each source factor was > 80 % (Table S1), indicating good robustness. In our previous study on Mt. Hua (Wu et al., 2022), insignificant changes in the corresponding emission sources were revealed during the air mass lifting process. Thus, the daytime samples from both sites were added together as one data matrix. Considering Q values and interpretability, four factors were obtained as the optimal solution after numerous testes with three to seven factors, and the input species matched well with the simulated ones, with significant correlations (R2>0.88).
In the above, MDL is the method detection limit, and the error fraction is set to 5 % for PM2.5 (Gao et al., 2018); WSOC, WSON, SO, NH, Mg2+, and Ca2+ are estimated to be 7 %, while the error fraction for the remaining species is 12 %. To reduce the error, the sample with missing data for individual species would be excluded rather than replaced by the mean value of the whole campaign.
2.5 Random forest analysis for WSON
Random forest (RF) analysis, as a powerful tool, has been used widely in regression and prediction problems regarding atmospheric pollutants; even the data have complex nonlinear relationships and interactions (Hu et al., 2017; Vu et al., 2019). To reveal the key factors that may affect the WSON formation during the air mass lifting process, an RF regression model was applied for the daytime samples at the MF and MS sites. Additionally, the potential factors herein, including pH, aerosol liquid-water content (ALWC), T, RH, NH, NH3(aq), NO2, nitrophenols, O3, and organic matter (OM), were regarded to be the predictors for WSON. In the RF model design, about 70 % of these original data were randomly divided into the training dataset to construct the RF model, and the rest were deemed to be the testing data for testing the model performance. There are two important parameters that are constantly being optimized in the model construction process, namely the number of trees grown (ntree) and the number of variables split at each node (nmtry). After numerous tests, ntree and nmtry were set to be 100 and 10 for MF data and 128 and 9 for MS data to achieve the best prediction accuracy. Furthermore, a 10-fold cross-validation technique was employed here to simultaneously tune model parameters and estimate model performance. Additionally, the statistical metrics, including the coefficient of determination (R2), mean square error (MSE) or root-mean-square error (RMSE), and mean absolute error (MAE), were established to evaluate the prediction accuracy of the model. As shown in Table S2, the predicted data for the testing dataset have strong correlativity with observation data, with small values for those error metrics. These results indicated a satisfactory performance of the RF model in explaining the importance of these factors to daytime WSON formation.
3.1 Enhanced light absorption of BrC in the mountainous atmosphere
Figure 1 shows the temporal variations in light absorption (abs365 nm) and the concentrations of fine particulate WSOC simultaneously observed at the mountain foot (MF) and mountainside (MS) sites. The variation patterns of water-soluble BrC (i.e., abs365 nm) at both sites were closely followed by WSOC (R2>0.70, Figs. 1 and S2); this indicated that BrC is an important part of WSOC, with the light absorption of BrC markedly increasing with decreases in light wavelengths. As summarized in Table 1, the averaged abs365 nm of BrC was 2.1 ± 1.4 M m−1 on the MS, approximately corresponding to 40 % of that (5.1 ± 2.4 M m−1) at the MF. The light absorbance level of BrC at the high-altitude MS site is in the same range as those reported from Chinese megacities such as Beijing (Cheng et al., 2016) and Xi'an (Wu et al., 2020), indicating a strong light absorption of BrC in the upper boundary layer over the Guanzhong basin of inland China. The absorption Ångström exponent (AAE) on the MS is 5.7 ± 1.3 (Table 1), slightly lower than that at the ground MF site (6.0 ± 0.5). Such a difference in AAE (p<0.05) is most likely related to the difference in the chemical composition of the chromophores between the two sites with different altitudes. The averaged mass absorption efficiency (MAE) on the MS (MAE365 nm, 0.67 ± 0.2 m2 gC−1) was almost equal to that at the MF (0.69 ± 0.2 m2 gC−1) but 30 %–40 % higher than those observed in Chinese megacities such as Beijing (Du et al., 2014) and Nanjing (Chen et al., 2018) (∼ 0.5 m2 gC−1 in summertime), further demonstrating the strong light absorption nature of BrC in the upper boundary layer of the Guanzhong basin of inland China.
a The abs550 nm-BC was calculated according to the mass absorption efficiency (MAE) of BC (black carbon) reported by Bosch et al. (2014); the light wavelengths for the abs365 nm-BrC and abs550 nm-BC are 365 and 550 nm, respectively.
Figure 2 shows the diurnal variations in abs365 nm and MAE365 nm at both sites during the campaign. At the MF site, a morning peak of abs365 nm driven by enhanced traffic emissions occurred at 08:00–12:00 (local time throughout) and then gradually decreased and reached a minimum at 12:00–16:00, with the lowest MAE at 365 nm wavelength (MAE365 nm, 0.57 ± 0.14 m2 gC−1) (Fig. 2a and b). Such a ground surface decease in the light absorption of BrC in the early afternoon can be attributed to the daytime boundary layer growth and photobleaching. This can be verified by the oxidation state of carbon (OSc) measured by the aerosol mass spectrometer, a higher value of which is indicative of a deeper degree of atmospheric oxidation (J. J. Li et al., 2019a). As seen in Fig. 3a, abs365 nm is negatively correlated with OSc, which is consistent with reported results of previous laboratory experiments (Lee et al., 2014; Zhao et al., 2015; Sumlin et al., 2017) and suggests that atmospheric aging can significantly diminish the light absorption of BrC. On the contrary, abs365 nm at the MS site was remarkably enhanced with boundary layer growth and peaked at 12:00–16:00 (Fig. 2a) despite the fact that the aerosol was further oxidized during the upward transport, as indicated by the higher OSc value at the MS site (Fig. 3b). The OSc variation between both sites coincided with that of , being a known proxy of whether aerosols are freshly emitted (> 1) or aged (< 1) (Fig. S3). Moreover, a moderately increased MAE365 nm was also observed in this process (Fig. 2b). As shown in Table 1, the light absorption of BrC at 365 nm relative to BC at 550 nm (abs365 nm-BrC and abs550 nm-BC) during the daytime on the MS was 0.28 ± 0.08, which is approximately 30 % higher than that at the MF (0.22 ± 0.08, Table 1). Our previous study at Mt. Hua found that changes in the sources of primary organic aerosols in the air masses transported from the MF to the MS were insignificant (Wu et al., 2022), indicating that there was no additional emission of BrC during the air mass upward transport. Thus, the enhanced light absorption of BrC relative to BC on the MS is solely ascribed to a secondary formation of absorbing BrC (Fig. 2c); the secondary BrC was highly light absorbing despite being more aged atmosphere aloft, as verified by a strongly positive correlation between MAE365 nm and OSc values at the MS site (Fig. S4).
To further elucidate the above hypothesis, a PMF analysis was applied for the source apportionment of the daytime abs365 nm at both sites. As seen in Fig. S5, four types of BrC sources were identified. In brief, fossil fuel combustion and biomass burning influenced by locally related emissions were primary sources for the surface BrC, which is consistent with observations made in other cities (Li et al., 2023; Wu et al., 2020; D. Wang et al., 2022). However, BrC at the MS site was produced dominantly from secondary formation, the contribution of which to the total BrC is 53 % and about twice that at the MF (Fig. 2d), further corroborating a substantial formation of BrC with relatively stronger light absorptivity during the air mass lifting process. These secondarily formed BrC chromophores engender more light absorption of high-altitude BrC compared with that of BC (or EC, Fig. 2c). A similar vertical profile of BrC in the upper troposphere (5–12 km) of the continental US was also observed by in situ aircraft measurements (Zhang et al., 2017).
3.2 Secondary formation of BrC in the air mass lifting process
Figure 4a illustrates the diurnal cycles of the N:C ratio of the water-soluble organic matter in PM2.5 measured by the high-resolution time-of-flight aerosol mass spectrometer. At the MF site, the N:C ratio did not vary much with time and even leveled off in the daytime, which indicates that the compositions of light-absorbing chromophores are similar throughout the day. Nonetheless, the diurnal pattern of the N:C ratio on the MS was analogous to that of abs365 nm and MAE365 nm, with a daily peak at 12:00–16:00, and a moderate positive correlation was also observed between the N:C ratio and abs365 nm (R2=0.38, P<0.01), suggesting that nitrogen-containing organic compounds (NOCs) make significant contributions to the BrC light absorption in the upper boundary layer. Such a result is consistent with the laboratory simulation, in which NOCs were reported to contribute up to 60 % of the absorbance of secondary BrC over a wavelength range of 300–400 nm (Lin et al., 2015). Moreover, the daytime N:C ratios were 20 % higher on the MS (0.066 ± 0.014) than those at the MF (Fig. 4a), indicating that additional NOCs were produced in the air mass lifting process. In fact, numerous N-containing organic fragments, including CxHyN and CxHyOzN at the MS site, were detected by the aerosol mass spectrometer, accounting for ∼ 13 % of the total water-soluble OM. Additionally, the fractional contribution of the above fragments on the MS was enhanced by approximately 10 % compared to that at the MF site, reaching up to ∼ 25 % during the day with low PM2.5 load (< 75 µg m−3) (Fig. S6). This suggested an enhanced formation of WSON during the air mass transport from the lower mountain foot site to the upper mountainside site. Since WSON on the MS moderately was positively correlated with light absorption of BrC at λ=365 nm (Fig. S7, R2=0.45, p<0.05), the enhancement in BrC light absorption on the MS can largely be attributed to secondary formation of NOCs during the air mass transport from the ground surface to the upper boundary layer.
Light-absorbing NOCs, including reduced nitrogen species (e.g., imidazoles and pyrazines) and oxidized ones (e.g., nitro-aromatics), can be generated via various types of gas- and particle-phase reactions, such as NH3-mediated carbonyl-to-imine reactions, nitration of aromatic compounds, and heterogeneous reactions of •OH and NO radicals with phenolic compounds (Moise et al., 2015; Laskin et al., 2015). The potential pathways and dominating factors for NOC formation at the MS site will be explored in the following sections.
3.3 Gas-phase formation of BrC in the air mass lifting process
Nitro-aromatic compounds (NACs) are strong light-absorbing compounds and are ubiquitous in the atmosphere. In this study, a total of six NACs in the PM2.5 samples were detected (Table S3), exhibiting significant correlations with abs365 nm at both sampling sites (Fig. S2c and d), which indicates the important impact of NACs on the aerosol light absorption. As seen in Fig. 5a, both the NAC concentration and the NAC/OC ratio decreased gradually at the MF, reaching the daily minimum at 12:00–16:00. Such an abatement in NACs was mainly attributed to the boundary layer expansion and an enhanced photooxidation (Fig. 3). Furthermore, the daytime NACs at the MF correlated well with (BbF+levoglucosan), being known as tracers for combustion emissions (R2>0.76, Fig. 5c), but were not correlated with gaseous NO2 (Fig. 5e), suggesting that most of the NACs at the ground surface site were directly emitted from combustion sources. This can be further verified by the strong positive correlation of NACs and CO prevailing in combustion exhausts (Fig. S8). As partial NACs at the MF site can be transported aloft by anabatic valley winds, a moderate correlation (R2=0.49, Fig. 5d) between NACs and (BbF+levoglucosan) was observed at the MS site. However, the moderate correlation between NO2 and NACs (R2=0.57, p<0.01, Fig. 5f) observed on the MS suggests a non-negligible formation of secondary NACs under the transport process. As revealed by previous studies, the NO3•/•OH oxidation of phenolic volatile organics in the presence of NOx can form numerous NACs, followed by partitioning to the condensed phase (Wang and Li, 2021; X. Li et al., 2021; Finewax et al., 2018); furthermore, the photolysis of nitrite in the aerosol aqueous phase can also lead to the nitration of phenol or catechol to generated NACs (Vione et al., 2005). However, there is a poor relationship between NACs and aerosol liquid-water content (ALWC; R2=0.34, P>0.05) and particulate phenol (R2<0.1), indicating a minor contribution of aqueous-phase formation to NACs aloft.
The preceding discussion provided reliable evidence that partial NACs could be formed by gas-phase reactions, but they only accounted for a very small fraction of OC (Fig. 5a–b), suggesting that gas-phase formation is probably not the major formation pathway of secondary NOCs during the air mass vertical transport. Further evidence for this hypothesis was provided by a random forest (RF) analysis, which was used as a metric for the degree of correlation between these influencing factors (ALWC, pH, T, NO2, NH, etc.) and WSON at both sampling sites (Figs. 4b and S9). As revealed by the RF model results, nitrophenols and gaseous NO2 were important influencing factors for the daytime WSON at the MF site (Fig. S9), the importance of which was explained by up to 35 % but only up to ∼ 15 % aloft (Fig. 4b), confirming a lesser importance of the gas-phase reactions for the light-absorbing-NOC formation in the vertical-transport process.
3.4 Aerosol aqueous formation of BrC in the air mass lifting process
As shown in Fig. 4b, RF analysis showed that the variation in the concentration of WSON in PM2.5 on the MS was largely affected by NH (23.0 %) and ALWC (17.3 %). Given a relatively strong correlation between WSON and NH (R2=0.70, Fig. 4c), we proposed that aqueous-phase reactions induced by ammonium constitute the major formation pathway for water-soluble NOCs on the MS. To further demonstrate such a hypothesis, we analyzed the nitrogen isotope composition (δ15N–NH) of ammonium in the PM2.5 samples at both sites, the analytical details of which have been described in our previous study (Wu et al., 2022). As seen in Fig. 4d, WSON showed a strong negative correlation with δ15N–NH, probably due to the irreversible reactions involving ammonia-favored 15N depletion in the particle form, as revealed by Heaton et al. (1997). In contrast, WSON at the MF presented a similar correlation with NH as that on the MS but did not correlate with δ15N–NH (Fig. S10a and b).
Previous studies have demonstrated the importance of in the formation of light-absorbing imidazoles and N-heterocycles from the carbonyls (e.g., glyoxal (Gly) and methylglyoxal (mGly) generated from oxidation of VOCs) (Y. Li et al., 2021; Moise et al., 2015; Kampf et al., 2012; Liu et al., 2023). Figure S11 depicts a simple reaction pathway for the above aqueous reactions, in which the chromophore products contain lower amounts of O and H atoms. Such a phenomenon was found for the daytime NOCs on the MS. As shown in Fig. 6, the and ratios of BrC in PM2.5 on the MS exhibited a strongly negative correlation with the ratio (R2=0.92 for and R2=0.84 for ). Considering the fact that Gly and mGly are abundant in the daytime atmosphere of Mt. Hua (Qi et al., 2023), the aqueous reactions of dicarbonyls with are probably the major pathway for yielding NOCs during the vertical transport.
The above aqueous reactions could also occur at the MF site, as depicted in Fig. S11, but these were insignificant compared to those at the MS site, attributable to the disparity in chemical compositions. Our previous study found that the ground surface MF aerosols were more acidic (pH = 2.9) and dominated by NH4HSO4, while the upper-boundary-layer MS aerosols were less acidic (pH = 3.4) and were dominated by abundant (NH4)2SO4. Such differences in aerosol acidity and chemical composition between the two sites can favor the formation of NOCs at the MS site, as is evident from a recent experimental observation by Y. Li et al. (2021), who found that the NOC yield on the (NH4)2SO4 seeds exposed to Gly or mGly vapor was relatively higher than that on NH4HSO4 seeds. Also, they found that mGly has a larger uptake coefficient on (NH4)2SO4 particles, with a relatively higher NOC yield compared to Gly, because mGly has a stronger interfacial attraction and thus has a more efficient nucleophilic addition involving carbenium ions (Y. Li et al., 2021). Our previous study showed that the summertime atmosphere of Mt. Hua is dominated by biogenic VOCs and that the concentration of fine particulate mGly is about 5 times that of Gly (Meng et al., 2014). Such a predominance of mGly over Gly and a less acidic aerosol aqueous-aerosol phase at the MF site are favorable for the formation of light-absorbing NOCs on (NH4)2SO4 particles, which could mainly be responsible for the enhanced light absorption of BrC at the mountainous site, with the ratio of the light absorption of BrC to BC being higher in the upper boundary layer than that in the ground surface.
3.5 Atmospheric implications
Our work provides an evolution profile of BrC during air mass vertical transport and highlights a secondary formation of BrC in this process, which could be responsible for the enhancement of BrC relative to BC in the upper boundary layer. Considering the longer lifetime of high-altitude BrC, it can disperse rapidly into a large area (Zhang et al., 2017), exerting a significant influence on regional climate that is even comparable to that of BC in the upper tropical troposphere (Jo et al., 2016). Moreover, we also revealed a vital role of aqueous-phase reactions in the secondary formation of BrC in the air mass lifting process, specifically the -induced reactions (e.g., the Maillard reaction) that can form NOCs with stronger light absorptivity. As ammonia and carbonyls such as glyoxal and methylglyoxal are ubiquitous in the troposphere, our work suggests that the above formation mechanism of the light-absorbing NOC aerosols could occur extensively in the troposphere.
In the past decade, the haze pollution in China has changed from the previous sulfate-dominated (SD) environment to the current nitrate-dominated (ND) environment due to the effective sulfur emission controls, which would significantly enhance the aerosol ALWC since nitrate is more hygroscopic than sulfate at a given RH and aerosol loading. As indicated by our previous observational evidence (Lv et al., 2023), a high ALWC load induced by abundant nitrate would efficiently promote more WSOC partitioning into aerosol phase, which may increase the BrC yield because WSOC contains numerous BrC precursors. With the increase in the relative abundance of nitrate to sulfate, nitrate-enhanced gas-to-particle partitioning of WSOC will become highly efficient in China in the near future, meaning that the BrC formation will be more active hereafter. Additionally, the national VOCs and NH3 emissions have remained at high levels and have even shown a slight increasing trend. The abundant NH3 not only participates in the formation of BrC but also affects BrC optical properties by regulating the aerosol acidity. To further reveal the impact on the BrC, the NH3 concentration and MAE365 nm value of water-soluble BrC in different regions of China were statistically explored on a national scale (Fig. 7a). As depicted in Fig. 7a, the spatial pattern of MAE365 nm is closely coincident with NH3 levels, with a robust positive correlation (R2=0.87). Such a spatial distribution pattern indicates that NH3-rich conditions are favorable for the formation of BrC with strong light absorptivity. China is one of the countries with the strongest NH3 emissions in the world due to the huge demand for N fertilizer (Van Damme et al., 2018); thus, atmospheric NH3 in China is much higher than that in Europe and the United States. This is probably one of the factors causing the higher concentrations of BrC with stronger light absorptivity in China compared to developed countries (Fig. 7b).
Synchronous observations of the optical properties and chemical compositions of atmospheric BrC were conducted at the MF and on the MS of Mt. Hua and revealed that the light absorption of BrC aloft was only ∼ 40 % of that at the surface owing to a dilution effect caused by planetary boundary layer upliftment. Additionally, the light absorption of BrC relative to black carbon was moderately enhanced in the lifting process of air masses from the MF to the MS, coinciding with the variation in the daytime MAE365 nm aloft, indicating a secondary formation of BrC. Such secondary BrC accounted for > 50 % of the total at the MS site, while the surface BrC mainly originated from direct combustion emissions, with a 55 % fractional contribution to the total.
The N:C ratio of WSOM was measured by offline AMS, of which the diurnal pattern was analogous to that of abs365 nm and MAE365 nm aloft, substantiating a considerable contribution of nitrogen-containing organic compounds (NOCs) to BrC light absorption. Furthermore, the daytime N:C ratio site was approximately 15 % higher on the MS than that at the MF, mainly due to a significant formation of secondary NOCs produced by -induced reactions (e.g., the Maillard reaction). Moreover, a robust positive relationship between MAE365 nm and NH3 load was statistically explored at the national scale, show strongly that abundant NH3 may be one of key factors for the high BrC load with strong light absorptivity in China compared to that in developed countries. Therefore, NH3 emission control in China is indispensable for further alleviating haze and BrC pollution in the country.
The data used in this study are freely available at https://doi.org/10.5281/zenodo.10926469 (Wu, 2024). Meteorological data and hourly PM2.5, NO2, and O3 concentrations can be obtained from https://doi.org/10.5281/zenodo.7413640 (Wu, 2022).
The supplement related to this article is available online at: https://doi.org/10.5194/acp-24-9263-2024-supplement.
GW designed the research and contributed the analytic tools. CW, CC, and JL collected the samples. CW, XL, KZ, and GW conducted the sample analysis. CW, SZ, and GW performed the data interpretation. CW and GW wrote the paper. All the authors contributed to the paper with useful scientific discussions.
The contact author has declared that none of the authors has any competing interests.
Publisher's note: Copernicus Publications remains neutral with regard to jurisdictional claims made in the text, published maps, institutional affiliations, or any other geographical representation in this paper. While Copernicus Publications makes every effort to include appropriate place names, the final responsibility lies with the authors.
This work was financially supported by the National Natural Science Foundation of China (grant nos. 42130704 and 42007202), the National Key R&D Plan, Ministry of Science and Technology of China (grant no. 2023YFC3706302) and the ECNU Happiness Flower program.
This research has been supported by the National Natural Science Foundation of China (grant nos. 42130704 and 42007202) and the National Key R&D Plan, Ministry of Science and Technology of China (grant no. 2023YFC3706302).
This paper was edited by Sergey A. Nizkorodov and reviewed by three anonymous referees.
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