Introduction

Black carbon (BC) is the most efficient light-absorbing component of atmospheric aerosols (Jacobson, 2001; Moffet and Prather, 2009; Cappa et al., 2012) and plays an important role in the global climate system (Ramanathan and Carmichael, 2008; Bond et al., 2013). However, accurately constraining the direct radiative forcing (DRF) of BC is a challenge owing to the discrepancy between observed and modelled estimates of BC light absorption (Gustafsson and Ramanathan, 2016). For example, a recent study has shown that the improved model-estimated DRF of BC ($+$0.21 Wm${}^{-\mathrm{1}}$) by including BC absorption enhancement and separately treating the aging and physical properties of fossil fuel and biomass burning BC was about 3 times lower than the values reported in the Intergovernmental Panel on Climate Change (IPCC) 5th assessment report ($+$0.6 Wm${}^{-\mathrm{2}}$), which suggested an overestimation of BC lifetime and an incorrect absorption attribution of light-absorbing organic compounds (brown carbon, BrC) (X. Wang et al., 2014).

BC particles are produced from incomplete combustion of fossil fuels, biofuels, and residual biomass (Novakov et al., 2003; Bond et al., 2004, 2007). Freshly emitted BC is mainly externally mixed and occurs in fractal-like agglomerates. Atmospheric BC particles undergo several aging processes, including coagulation with other particles, condensation of vapours onto surfaces, and chemical oxidation (Slowik et al., 2004; Zhang et al., 2008; Petzold et al., 2013). Individual BC particles become coated (i.e., internally mixed) with sulfate, ammonium, organics, nitrate, and water (Bond and Bergstrom, 2006; Cheng et al., 2006; Schwarz et al., 2008; Ervens et al., 2010; Zaveri et al., 2010). Aging processes dramatically change the morphology, hygroscopicity, and mixing state of BC-containing particles, thereby altering their optical properties and the magnitude of their contribution to climate forcing (Jacobson, 2001; Bond and Bergstrom, 2006; Schwarz et al., 2008; Zhang et al., 2008).

The light absorption enhancement of BC particles caused by coating is quantified by $E_{\mathrm{abs}}$, the ratio of the absorption coefficients of coated and bare BC. $E_{\mathrm{abs}}$ introduces a large uncertainty in the DRF of BC, which is the second most important contributor to global warming (Jacobson, 2001; S. Liu et al., 2015). Current models simply adopt a constant enhancement value ($\sim$ 1.5 or 2) for the calculation of DRF of BC (Cappa et al., 2012; Bond et al., 2013; X. Wang et al., 2014). In contrast, reported $E_{\mathrm{abs}}$ values vary widely (Peng et al., 2016; Liu et al., 2017). Field measurements along the California coast and ground site in Sacramento (California) (Cappa et al., 2012), Shenzhen (South China) (Lan et al., 2013), the Nagoya urban area (Japan) (Nakayama et al., 2014), and urban Los Angeles (USA) (Krasowsky et al., 2016) found negligible absorption enhancement ($E_{\mathrm{abs}}$ < 1.1) and weak dependence on the extent of photochemical aging (estimated from the value of $-$log([${\mathrm{NO}}_x$] $/$ [${\mathrm{NO}}_y$]), where ${\mathrm{NO}}_x$ $=$ $\mathrm{NO}$ $+$ ${\mathrm{NO}}_{\mathrm{2}}$ and ${\mathrm{NO}}_y$ includes the sum of ${\mathrm{NO}}_x$ and its oxidation products; Deolal et al., 2012). Biomass burning measurements showed an absorption enhancement of 1.7 at $\mathit{\lambda }$ $=$ 532 nm (Lack et al., 2012). Recent observations in Chinese cities (Peng et al., 2016; X. Cui et al., 2016; Xu et al., 2016; Chen et al., 2017; Cheng et al., 2017; Q. Wang et al., 2017) provide evidence for a higher $E_{\mathrm{abs}}$ in polluted conditions, with values ranging from 2 to 3. The mechanisms responsible for enhancing BC absorption remain elusive due to the complexity of the aging process and its varied sources. More studies in receptor locations with a longer BC aging time are required to better constrain $E_{\mathrm{abs}}$ (Gustafsson and Ramanathan, 2016; Boucher et al., 2016).

In this work, the influence of photochemical aging on BC mixing state, $E_{\mathrm{abs}}$, and aerosol single-scattering albedo (SSA, $\mathit{\omega }$, defined as the ratio of scattering to extinction coefficient) at a rural site in east China during the summer was studied by using a volatility tandem differential mobility analyser (VTDMA) and a thermal denuder (TD) approach combined with a cavity-enhanced albedometer operating at $\mathit{\lambda }$ $=$ 532 nm. In summer, ${\mathrm{O}}_x$ (${\mathrm{O}}_x$ $=$ ${\mathrm{O}}_{\mathrm{3}}$ $+$ ${\mathrm{NO}}_{\mathrm{2}}$) exhibits good correlation with secondary pollutants (Zhou et al., 2014; Cevik et al., 2016; Ji et al., 2016). The concentration of ${\mathrm{O}}_x$ was used as a proxy for atmospheric photochemical aging (Hallquist et al., 2016; Q. Wang et al., 2017). We find that photochemical aging results in the growth of particle coating and higher fractions of internally mixed BC particles. The modelling and parameterization of $E_{\mathrm{abs}}$ and SSA capture the variability of BC coating amount and the particle absorption and provide a plausible new method to better constrain the contribution of BC to the DRF.

Experimental

The field site

Measurements were performed at Shouxian National Climatological Observatory (32${}^{\circ }$25${}^{\prime }$47.8${}^{\prime \prime }$ N, 116${}^{\circ }$47${}^{\prime }$38.4${}^{\prime \prime }$ E) in Anhui Province from 16 June to 23 July 2016. Shouxian County is located in China's north–south climate transition zone and is affected by the east Asian monsoon. The new observatory is situated about 15 km south of the previous, historically important observation site (Fan et al., 2010; Li et al., 2011; Deng et al., 2012); it is a rural background site surrounded by basic farmland protection areas and has no significant industrial pollution sources or tall buildings nearby.

Instruments were installed in a temperature-controlled room with two sample inlets about 1 m above the roof (Fig. S1 in the Supplement). Each inlet consisted of one PM${}_{\mathrm{2.5}}$ cyclone (BGISCC2.654) with a 50 % cut point at 2.5 $\mathrm{\mu }$m, and was first dried below 40 % relative humidity (RH) using a diffusion drier. The sampling rates at both inlets were controlled with mass flow controllers (MFCs) and set at 10 L min${}^{-\mathrm{1}}$. One of the inlets was used for the volatility measurements; the other inlet stream was used for the optical measurements. Trace gas pollutants such as $\mathrm{CO}$, ${\mathrm{NO}}_x$, ${\mathrm{SO}}_{\mathrm{2}}$, and ${\mathrm{O}}_{\mathrm{3}}$ were, respectively, measured by Thermo 48i, 42i, 43i, and 49i analyser.

Volatility measurement

Size-resolved mixing state of BC was measured with a VTDMA developed in-house. The VTDMA was structurally similar to other systems described in the literature (Cheng et al., 2009, 2012; Wehner et al., 2009; Cheung et al., 2016) and comprised the following:

• an electrostatic classifier (DMA, differential mobility analyser, TSI 3080) for the initial selection of monodisperse particles;

• a custom-built stainless steel heating tube (inner diameter of 0.77 cm, 80 cm long, and heated to 300 $\pm$ 5 ${}^{\circ }$C) for removing nonrefractory particulate matter; and

• a scanning mobility particle sizer (SMPS, TSI 3936) comprising a DMA (TSI 3080) and a condensation particle counter (CPC, TSI 3776) for measuring the size distribution of the heated sample in the range of 15 to 661 nm.

Optical measurement

The optical properties of dry PM${}_{\mathrm{2.5}}$ particles were measured with a cavity-enhanced albedometer operating at $\mathit{\lambda }$ $=$ 532 nm (Zhao et al., 2014; Xu et al., 2016). The albedometer combined broadband cavity-enhanced spectroscopy (BBCES) with an integrating sphere (IS) for direct, in situ, and simultaneous measurement of extinction ($b_{\mathrm{ext}}$) and scattering ($b_{\mathrm{scat}}$) coefficients, thus allowing the calculation of the absorption ($b_{\mathrm{abs}}$) coefficient and SSA. Compared with our previously reported 470 nm system (Zhao et al., 2014; Xu et al., 2016), the new 532 nm albedometer was modified by inserting a quartz tube within the IS to prevent the degradation of the IS reflectivity and to reduce the sample's residence time (Dial et al., 2010; Onasch et al., 2015). The sample volume of the albedometer was about 0.3 L and the flow rate was 1.5 L min${}^{-\mathrm{1}}$ at atmospheric pressure.

The details of the evaluation of the instrument have been described in our previously published paper (Zhao et al., 2014; Xu et al., 2016; Fang et al., 2017). Detection limits of each parameter were determined by using an Allan variance analysis. With a 30 s integration time (an average of 300 individual spectra, each with 100 ms exposure time), the detection limits under ambient aerosol loading condition for the scattering and extinction measurements were better than 0.15 and 0.12 Mm${}^{-\mathrm{1}}$, respectively. The accuracy of the instrument was evaluated with laboratory-generated, NIST traceable monodispersed polystyrene latex (PSL) spheres. During field observations, the optical system was calibrated with ${\mathrm{N}}_{\mathrm{2}}$, ${\mathrm{CO}}_{\mathrm{2}}$, and PSL every 2 weeks.

The total uncertainties (summed in quadrature of each error source) in extinction, scattering, absorption coefficients, and SSA measurements were estimated to be less than 4 %, 3 %, 5 %, and 4 %, respectively. Uncertainty in extinction mainly arose from the uncertainties in mirror reflectivity (1 – $R$, $\sim$ 1 %), the ratio of cavity length to the cell length containing the air sample when the cavity mirrors were purged ($R_{\mathrm{L}}$, $\sim$ 3 %), and particle losses in the cavity ($\sim$ 2 %). Uncertainty in the scattering measurement was mainly caused by uncertainties in the experimentally determined scattering calibration coefficient ($K$', $\sim$ 2 %), particle losses in the cavity ($\sim$ 2 %), and the truncated fraction of total scattering. (Since most particles in the observation were smaller than 1 $\mathrm{\mu }$m, the uncertainty associated with truncation angle was < 1 %, as discussed in Sect. S2 in the Supplement.) Since measurements of the extinction and scattering coefficients were of the identical sample, particle losses do not affect the SSA measurement (Zhao et al., 2014; Xu et al., 2016).

The sampled ambient air was divided into two channels: the first channel was directly pumped into the albedometer to measure the ambient absorption coefficient ($b_{\mathrm{abs},\mathrm{ambient}}$); another channel was installed with a TD (Dekati Ltd., Finland) operating at 300 ${}^{\circ }$C to evaporate semi-volatile particulate components for measuring the absorption coefficient of refractory BC (rBC; $b_{\mathrm{abs},\mathrm{TD}}$) (Olson et al., 2015). These two channels were switched automatically every 5 min with an electric ball valve. The flow rate of the TD was 10 L min${}^{-\mathrm{1}}$. Particle losses inside the TD are discussed in detail in Sect. S3 in the Supplement and are generally caused by diffusional and thermophoretic processes (Wehner et al., 2002; Fierz et al., 2007). The optical loss of the TD of ambient aerosol was estimated to be $\sim$ 32 %. The measured $b_{\mathrm{abs},\mathrm{TD}}$ was corrected with the particle losses for further calculation of the absorption enhancement ($E_{\mathrm{abs}}$ $=$ $b_{\mathrm{abs},\mathrm{ambient}}$ $/$ $b_{\mathrm{abs},\mathrm{TD}}$). The total uncertainty in $E_{\mathrm{abs}}$ measurement was about 9 % (mainly contributed by uncertainties in the measurement of $b_{\mathrm{abs},\mathrm{ambient}}$ (5 %), $b_{\mathrm{abs},\mathrm{TD}}$ (5 %), and particle losses inside TD (6 %)).

Time series of CO, ${\mathrm{NO}}_{\mathrm{2}}$, ${\mathrm{O}}_{\mathrm{3}}$, and ${\mathrm{O}}_x$ (${\mathrm{O}}_{\mathrm{3}}$ $+$ ${\mathrm{NO}}_{\mathrm{2}}$) concentrations, as well as the concentrations of PM${}_{\mathrm{2.5}}$ and PM${}_{\mathrm{1.0}}$ during the measurement period.

[Figure omitted. See PDF]

Results and discussion

The concentrations of PM${}_{\mathrm{1.0}}$, PM${}_{\mathrm{2.5}}$, and trace pollutants ($\mathrm{CO}$, ${\mathrm{NO}}_{\mathrm{2}}$ and ${\mathrm{O}}_{\mathrm{3}}$) measured at the station over the measurement period are shown in Fig. 1. For assessing the effect of photochemical oxidation on the aerosol optical properties, the time series of the ${\mathrm{O}}_x$ concentration is also shown in the figure. Both ${\mathrm{O}}_x$, PM${}_{\mathrm{1}}$ and PM${}_{\mathrm{2.5}}$ concentrations have clear diurnal cycles. The corresponding meteorological conditions are shown in the Supplement Fig. S8. The average ambient temperature ($T$), relative humidity (RH), and wind direction (WD) were 26.0 $\pm$ 3.3 ${}^{\circ }$C, 90 $\pm$ 11 %, and 2.0 $\pm$ 1.1 m s${}^{-\mathrm{1}}$, respectively. The prevailing winds were southerly. Generally, the low wind speed favoured the accumulation of pollutants, and the RH was also quite high. The average concentrations of PM${}_{\mathrm{2.5}}$ and PM${}_{\mathrm{1.0}}$ were 28 $\pm$ 14 and 25 $\pm$ 13 $\mathrm{\mu }$g m${}^{-\mathrm{3}}$, respectively. The 48 h backward trajectories ending at 500 m above ground level at the Shouxian site are shown in Fig. S9 in the Supplement. The trajectories were aggregated into five groups after taking into account the wind direction, speed, and the geometric distance between individual trajectories (S. Wang et al., 2017). The air masses in clusters 1, 3, 4, and 5 originated from long-range transport with high speeds for over 40 h. Air masses in cluster 2 originated from the vicinity of Anhui province and moved slowly. The long aging time and residence time of the air masses led to well-aged particles before arriving at the observation site. All air masses were at relatively low altitudes (< 1500 m) and remained within the boundary layer over this 2-day period.

Examples of the particle number size distributions of ambient aerosol (black points), as well as the VTDMA measured room temperature bypass sample ($\sim$ 25 ${}^{\circ }$C, blue open circles), and the sample passed through a custom-built heating tube at 300 ${}^{\circ }$C ($D_{\mathrm{p},\mathrm{300}{}^{\circ }\mathrm{C}}$, red points) for the initial selected diameter of 150 nm ($D_{\mathrm{p}}$). The corresponding Gaussian fit of the size distributions are shown as black, blue, and red lines. The size distribution obtained after heating was divided into three size ranges according to previously reported empirical cutting diameters. (1) Particles with diameters $D_{\mathrm{p},\mathrm{300}{}^{\circ }\mathrm{C}}$ $/$ $D_{\mathrm{p}}$ < 45 % were denoted as “high-volatility” (HV) and were not considered to be BC. (2) Particles with diameters 45 % < $D_{\mathrm{p},\mathrm{300}{}^{\circ }\mathrm{C}}$ $/$ $D_{\mathrm{p}}$ < 82 % were considered to be internally mixed BC particles (a non-volatile core coated with a volatile shell) and were denoted as “medium-volatility” (MV). (3) Particles with diameters 82 % < $D_{\mathrm{p},\mathrm{300}{}^{\circ }\mathrm{C}}$ $/$ $D_{\mathrm{p}}$ < 120 % were denoted as “low-volatility” (LV) and were considered to be externally mixed BC.

[Figure omitted. See PDF]

Size-resolved mixing state of BC

Following the approach of Philippin et al. (2004), Cheng et al. (2009), and Wehner et al. (2009), most compounds were assumed to be volatilized at 300 ${}^{\circ }$C and the residual non-volatile particles were regarded as rBC. An example of the measured size distribution is shown in Fig. 2. The heated size distribution was divided into three size ranges – “high-volatility” (HV), “medium-volatility” (MV), and “low-volatility” (LV) – to calculate the number fraction of internally mixed BC particles: $${\displaystyle }{F}_{\mathrm{in}}=N_{\mathrm{MV}}/(N_{\mathrm{MV}}+N_{\mathrm{LV}}),$$ where $N_{\mathrm{MV}}$ is the number concentration of MV particles and is considered to be internally mixed BC. $N_{\mathrm{LV}}$ is the number concentration of LV and is considered to be externally mixed BC (Cheng et al., 2009, 2012; Wehner et al., 2009; Cheung et al., 2016).

Correlation between the hourly-averaged number fractions of internally mixed BC ($F_{\mathrm{in}}$) and the photochemical oxidant (${\mathrm{O}}_x$) mixing ratios for different size bins (50, 100, 150, 200, 250, and 300 nm). Data points are colour-coded with respect to the concentrations of CO (an indicator of primary BC emissions). Low $F_{\mathrm{in}}$ values generally appear at high CO concentrations, and vice versa. For 150, 200, 250 and 300 nm diameters, $F_{\mathrm{in}}$ values increased with oxidant concentration. The slope of the linear regression (red line) is representative of the oxidation rate of $F_{\mathrm{in}}$ (the fit standard error is shown in brackets).

[Figure omitted. See PDF]

To assess the influence of atmospheric photochemical aging on the mixing state of BC, scatter plots of $F_{\mathrm{in}}$ at different diameters and ${\mathrm{O}}_x$ concentrations are shown in Fig. 3. Data points are colour-coded with respect to the concentrations of CO, which is related to primary BC emission. The value of $F_{\mathrm{in}}$ reflects the competition between fresh emission and atmospheric aging (Cheng et al., 2012). The freshly emitted particles have lower $F_{\mathrm{in}}$ values, while the aging process converts externally mixed particles into internally mixed and then increases the value of $F_{\mathrm{in}}$. In this work, low $F_{\mathrm{in}}$ values tended to appear at high CO concentrations, consistent with freshly emitted BC. The observed decreasing trends in $F_{\mathrm{in}}$ with ${\mathrm{O}}_x$ for particle diameters of 50 and 100 nm were probably due to the increment of the relative contribution of fresh emissions in the small particle size range.

A positive correlation between $F_{\mathrm{in}}$ and ${\mathrm{O}}_x$ was observed for particle diameters of 150, 200, 250, and 300 nm, respectively. The corresponding oxidation rates of $F_{\mathrm{in}}$ were 0.07 and 0.12 % ppb${}^{-\mathrm{1}}$ and 0.16 %, and 0.17 % ppb${}^{-\mathrm{1}}$. Particles of these sizes have greater internal mixing and may be more susceptible to photochemical oxidation processes. Very recently, Q. Wang et al. (2017) reported a similar correlation between the number fraction of thickly coated rBC ($F_{\mathrm{rBC}}$, the mixing state of individual rBC was measured with single particle soot photometer, SP2) and ${\mathrm{O}}_x$ concentration in highly polluted megacities. The reported oxidation rates of $F_{\mathrm{rBC}}$ were 0.58 % ppb${}^{-\mathrm{1}}$ for Beijing and 0.84 % ppb${}^{-\mathrm{1}}$ for Xi'an, respectively. Photochemical aging resulted in higher amounts of internally mixed BC and a larger fraction of thickly coated BC under more oxidizing conditions.

Time series of the optical parameters and absorption enhancement ($E_{\mathrm{abs}}$) at $\mathit{\lambda }$ $=$ 532 nm at a time resolution of 10 min. Properties shown are the extinction ($b_{\mathrm{ext}}$), scattering ($b_{\mathrm{scat}}$), and absorption coefficients ($b_{\mathrm{abs}}$), the SSA ($\mathit{\omega }$) of ambient particles ($b_{\mathrm{ambient}}$), and particles passed though the thermodenuder ($b_{\mathrm{TD}}$) at 300 ${}^{\circ }$C (after correcting for particle losses).

[Figure omitted. See PDF]

Temporal and diurnal variations in optical properties

Time series of the measured optical properties are shown in Fig. 4 and include the extinction ($b_{\mathrm{ext}}$), scattering ($b_{\mathrm{scat}}$), and absorption ($b_{\mathrm{abs}}$) coefficients, the SSA for ambient particles ($b_{\mathrm{ambient}}$) and for particles passed through TD ($b_{\mathrm{TD}}$), and the corresponding $E_{\mathrm{abs}}$. The mean (and standard deviation) of $b_{\mathrm{ext},\mathrm{ambient}}$, $b_{\mathrm{scat},\mathrm{ambient}}$, and $b_{\mathrm{ext},\mathrm{TD}}$, $b_{\mathrm{scat},\mathrm{TD}}$ were 92 $\pm$ 64, 81 $\pm$ 55, 12 $\pm$ 7, and 6.5 $\pm$ 4.1 Mm${}^{-\mathrm{1}}$, respectively. The scattering fraction remaining ($b_{\mathrm{scat},\mathrm{TD}}$ $/$ $b_{\mathrm{scat},\mathrm{ambient}}$) was about 0.09 $\pm$ 0.05 and indicated that most of the coating species evaporated in the TD at 300 ${}^{\circ }$C. Our value is comparable to the value of 0.08 $\pm$ 0.02 reported by Nakayama et al. (2014). The change in the morphology during heating was negligible.

The observed diurnal variation in aerosol optical parameters (extinction ($b_{\mathrm{ext}}$), scattering ($b_{\mathrm{scatt}}$), absorption ($b_{\mathrm{abs}}$) coefficients, and SSA ($\mathit{\omega }$)) of ambient particles ($b_{\mathrm{ambient}}$, a–c, g) and particles passed through the thermodenuder at 300 ${}^{\circ }$C after correcting for particle losses ($b_{\mathrm{TD}}$, d–f, h). The absorption enhancement ($E_{\mathrm{abs}}$, i) was calculated as the ratio between $b_{\mathrm{abs},\mathrm{ambient}}$ $/$ $b_{\mathrm{abs},\mathrm{TD}}$. The mass concentrations of PM${}_{\mathrm{2.5}}$ (j) and the mixing ratios of CO (k) and ${\mathrm{O}}_x$ (l) are also shown for assessing the effect of photochemical oxidation. The optical measurement at $\mathit{\lambda }$ $=$ 532 nm covered the period 16 June to 23 July 2016. The box and whisker plots show the mean (dots), median (centre solid line), lower and upper quartile (boxes), and 5th and 95th percentile (whiskers).

[Figure omitted. See PDF]

The observed diurnal variation in optical parameters ($b_{\mathrm{ext},\mathrm{ambient}}$, $b_{\mathrm{scat},\mathrm{ambient}}$, ${\mathit{\omega }}_{\mathrm{ambient}}$, $b_{\mathrm{abs},\mathrm{ambient}}$,$b_{\mathrm{ext},\mathrm{TD}}$,$b_{\mathrm{scat},\mathrm{TD}}$, $b_{\mathrm{abs},\mathrm{TD}}$, ${\mathit{\omega }}_{\mathrm{TD}}$, $E_{\mathrm{abs}}$), mass concentrations of PM${}_{\mathrm{2.5}}$, as well as the mixing ratio of CO and the photochemical oxidant (${\mathrm{O}}_x$) are shown in Fig. 5. Broadly similar diurnal patterns were observed for the extensive optical properties ($b_{\mathrm{ext},\mathrm{ambient}}$, $b_{\mathrm{scat},\mathrm{ambient}}$, $b_{\mathrm{abs},\mathrm{ambient}}$, $b_{\mathrm{ext},\mathrm{TD}}$, $b_{\mathrm{scat},\mathrm{TD}}$, $b_{\mathrm{abs},\mathrm{TD}}$) of ambient particles and particles passed through the thermodenuder, and the mass concentrations of PM${}_{\mathrm{2.5}}$. A strong diurnal variation and similar diurnal patterns in ${\mathit{\omega }}_{\mathrm{ambient}}$, ${\mathit{\omega }}_{\mathrm{TD}}$, $E_{\mathrm{abs}}$, and ${\mathrm{O}}_x$ were observed. Patterns of the extensive optical properties and PM${}_{\mathrm{2.5}}$ indicate some local particle emissions from early morning anthropogenic activities. While these changes are radiatively significant, changes in PM${}_{\mathrm{2.5}}$ during the early daylight period are weak, suggesting that emitted particles are small and contribute little to the overall particle mass concentration. The SSA shows that particles tend to be more strongly absorbing in early morning than later in the day; however, measured SSA values are not especially low (mean ${\mathit{\omega }}_{\mathrm{ambient}}$ $\ge$ 0.85), consistent with the background nature of the Shouxian site. Thus, freshly emitted particles are therefore relatively unimportant at this site. CO concentrations show minor diurnal variation, consistent with the regional nature of air masses at this site.

Daytime increases in the boundary layer into the mid-afternoon are especially evident in the PM${}_{\mathrm{2.5}}$ concentration profile. In contrast, ambient scattering and extinction profiles are broadly flat over the same period, indicating more intense photochemical processing and extensive secondary aerosol generation. The same effect is responsible for the mid-afternoon maximum in the intensive optical property ${\mathit{\omega }}_{\mathrm{ambient}}$.

Relationship between (a) $\mathit{\omega }$, (b) ${\mathit{\omega }}_{\mathrm{TD}}$, and (c) $E_{\mathrm{abs}}$ with ${\mathrm{O}}_x$ concentrations. The gray circles are the measurement data with 1 h time resolution. The hourly averaged $\mathit{\omega }$, ${\mathit{\omega }}_{\mathrm{TD}}$, and $E_{\mathrm{abs}}$ were then binned in ${\mathrm{O}}_x$ with the same data points (80 points) in each bin. The corresponding mean (solid dot), median (centre solid line), lower and upper quartile (boxes), and 10th and 90th percentile (whisker) are shown as the box and whisker plots. The corresponding frequency distribution of each parameters is shown in (d)–(g).

[Figure omitted. See PDF]

Influence of photochemical aging on $E_{\mathrm{abs}}$ and SSA

SSA is one of the most relevant intensive optical properties (Jo et al., 2017) because it describes the relative strength of the aerosol scattering and absorption capacity and is a key input parameter in climate models. Changes in particle size, morphology, chemical composition, and mixing state caused by atmospheric chemical aging processes will alter SSA. The relationships between hourly-averaged $\mathit{\omega }$, ${\mathit{\omega }}_{\mathrm{TD}}$, and $E_{\mathrm{abs}}$ with hourly-averaged ${\mathrm{O}}_x$, as well as the scattering plot of hourly averaged $\mathit{\omega }$, ${\mathit{\omega }}_{\mathrm{TD}}$, and $E_{\mathrm{abs}}$ that binned in ${\mathrm{O}}_x$ (with the same data points in each bin) and the frequency distributions of the hourly averaged data are shown in Fig. 6. Approximately 90 % of the values of $\mathit{\omega }$, ${\mathit{\omega }}_{\mathrm{TD}}$, and $E_{\mathrm{abs}}$ during the measurement were within the range of 0.80–0.91, 0.43–0.65, and 1.0–3.5, respectively.

During the summer, ${\mathrm{O}}_{\mathrm{3}}$ has a central role in the generation of secondary aerosol. Positive correlations between $\mathit{\omega }$, ${\mathit{\omega }}_{\mathrm{TD}}$, and ${\mathrm{O}}_x$ concentrations were observed in our measurements (Fig. 6a and b), which suggests that higher ${\mathrm{O}}_x$ actually increases the mass fraction of secondary aerosol particles and the overall ensemble of particle material and SSA. Our result is consistent with Beijing summer observations, where SSA was linearly correlated with the mass fractions of secondary aerosols (Han et al., 2017). The increase in ${\mathit{\omega }}_{\mathrm{TD}}$ resulted from incomplete vaporization of non-volatile constituents in the heating tube (Cheung et al., 2016), the generation of low-volatility oxygenated organic aerosol during photochemical aging (Paciga et al., 2016), and the changes in BC morphology (Radney et al., 2014). Summertime volatility measurement of organic aerosol in the megacity Paris shown that about 10 % mass fraction remained with a TD operating at 180 ${}^{\circ }$C (Paciga et al., 2016). However, recent research demonstrated that the remaining non- and low-volatile coating has a minor impact on the absorption measurement of heated particles using TD operating at 250 ${}^{\circ }$C (S. Liu et al., 2015). Theoretical and experiment results show that aging causes the dramatic changes in BC particle morphology (China et al., 2015; He et al., 2015, 2016; Scarnato et al., 2013; Y. Wang et al., 2017) and leads to more compact black carbon with higher scattering cross sections (Peng et al., 2016; Y. Wu et al., 2018), which in turn results in an increase in ${\mathit{\omega }}_{\mathrm{TD}}$ (Radney et al., 2014; Forestieri et al., 2018). In this regard, the rise in ${\mathit{\omega }}_{\mathrm{TD}}$ with increasing ${\mathrm{O}}_x$ concentration can be used as an indicator of the changes in BC morphology. The values of ${\mathit{\omega }}_{\mathrm{TD}}$ remained stable for ${\mathrm{O}}_x$ mixing ratios larger than 45 ppbv, which possibly indicate that the change in the proportion of non-volatile constituents or BC morphology was negligible.

$E_{\mathrm{abs}}$ also rose with higher ${\mathrm{O}}_x$ mixing ratios (Fig. 6c and Fig. S10 in the Supplement), but with a different pattern compared to $\mathit{\omega }$ and ${\mathit{\omega }}_{\mathrm{TD}}$. From the scattering plot of the hourly averaged $E_{\mathrm{abs}}$ that was binned in ${\mathrm{O}}_x$, a monotonic growth of $E_{\mathrm{abs}}$ with increasing ${\mathrm{O}}_x$ can be observed below 45 ppbv ${\mathrm{O}}_x$ (from 2.1 to 2.6). For ${\mathrm{O}}_x$ mixing ratios between 45 and 57 ppbv, $E_{\mathrm{abs}}$ values remained constant ($\sim$ 2.4). The small drop in $E_{\mathrm{abs}}$ value for the ${\mathrm{O}}_x$ bin larger than 57 ppbv was probably caused by the limited data numbers for ${\mathrm{O}}_x$ larger than 75 ppbv and was statistically insignificance. The most frequently occurring value of $E_{\mathrm{abs}}$ for the whole measurement was $\sim$ 1.7.

Four selected case studies of the variations in hourly-averaged $\mathit{\omega }$, ${\mathit{\omega }}_{\mathrm{TD}}$, and $E_{\mathrm{abs}}$ as a function of hourly-averaged ${\mathrm{O}}_x$ concentrations. (a, b) Case 1: on 16 June 2016; winds were typically from the north. (c, d) Case 2: 25 to 26 June 2016, wind direction varied from north to south. (e, f) Case 3: 7 to 8 July 2016; winds were mainly from the southeast. (g, h) Case 4: 9 to 12 July 2016; winds were mainly from the northeast. The daytime (from 06:30 to 18:30 local time) and nighttime (from 18:30 to 06:30 local time) data have been marked in different colours and symbols. The slope of the linear regression (red and blue lines, only for daytime data) is representative of the oxidation rate of each parameter (the fit standard error is shown in brackets).

[Figure omitted. See PDF]

Since the emission sources, weather conditions, and aging degrees of BC particles varied from day to day, the relationship between $E_{\mathrm{abs}}$ and atmospheric chemistry is rather complex. Four selected cases with different wind directions were used to demonstrate this complexity (as shown in Fig. 7, the day- and nighttime data were separated). The corresponding wind directions and speeds, RH values, and CO concentrations are shown in Fig. S10 in the Supplement. The patterns of $E_{\mathrm{abs}}$ with ${\mathrm{O}}_x$ were different for air masses from different directions. For cases 1 and 2, the mean values of $E_{\mathrm{abs}}$ were comparable (1.9 $\pm$ 0.2 for case 1 and 1.8 $\pm$ 0.6 for case 2), and the hourly-averaged $\mathit{\omega }$ and ${\mathit{\omega }}_{\mathrm{TD}}$ grew with increasing ${\mathrm{O}}_x$ in both cases. In case 1, $E_{\mathrm{abs}}$ ranged from 1.5 to 2.3, with a growth rate of $\sim$ 0.01 ppbv${}^{-\mathrm{1}}$ in the daytime. During this period, winds were typically from the north, which corresponding to a short transported pathway of air masses (Fig. S9 in the Supplement). The low degree of aging led to a small $E_{\mathrm{abs}}$ value. In case 2, $E_{\mathrm{abs}}$ ranged from 1.1 to 3.7, and the corresponding growth rates was $\sim$ 0.05 ppbv${}^{-\mathrm{1}}$ in the daytime. It is worth noting that the low $E_{\mathrm{abs}}$ values in this period corresponded to low $\mathit{\omega }$ values (Fig. 7c), which indicated the influence on the local emissions on $E_{\mathrm{abs}}$. For cases 3 and 4, $\mathit{\omega }$ and ${\mathit{\omega }}_{\mathrm{TD}}$ increased slowly with ${\mathrm{O}}_x$ in comparison with cases 1 and 2. Monotonic relationships were found here, with growth rates of $\sim$ 0.01 and 0.05 ppbv${}^{-\mathrm{1}}$. The large $E_{\mathrm{abs}}$ values in the daytime than nighttime suggested that photochemistry plays a positive effect on the increment of absorption enhancement. These results demonstrated the complex influence of emission and aging degree of BC particles in modifying the light absorption of BC-containing particles. For air masses from different directions, the relationship between $E_{\mathrm{abs}}$ and ${\mathrm{O}}_x$ may be different.

A survey of some field measured $E_{\mathrm{abs}}$ values.

A list of recently reported $E_{\mathrm{abs}}$ values is shown in Table 1. The averaged and standard deviation of $E_{\mathrm{abs}}$ value at $\mathit{\lambda }$ $=$ 532 nm for this work was 2.3 $\pm$ 0.9, which agreed well with values from Boulder using the same TD method combined with a photoacoustic spectrometer (PAS) (Lack et al., 2012) from Yuncheng (X. Cui et al., 2016) and Jinan (Chen et al., 2017) using an aerosol filtration–dissolution (AFD) method and from Beijing (Peng et al., 2016; Xu et al., 2016; Cheng et al., 2017) based on the mass absorption efficiency (MAE) method. Our result is also comparable to that reported in laboratory studies of thickly coated BC particles where $E_{\mathrm{abs}}$ ranged from 1.8 to 2.4 (Bond et al., 2013).

A chamber study by Peng et al. (2016) suggested that the primary BC was in a chain-like structure with low particle density and then collapsed to a semi-spherical particle. During this stage, there is no significant absorption enhancement ($E_{\mathrm{abs}}$ ranged from 1.0 to 1.4). With continued coating growth with several hours' aging in the chamber, the semi-spherical particle was further collapsed and finally transformed to fully compact spherical, internally mixed BC particles ($E_{\mathrm{abs}}$ increased to $\sim$ 2.3–2.4) (Gustafsson and Ramanathan, 2016). Recent morphologically constrained modelling developed by Y. Wu et al. (2018) demonstrated that after full aging, the BC particles became a more compact aggregation, which leads to a stable range of $E_{\mathrm{abs}}$ (averaged value $\sim$ 2.5, with a minimum value of $\sim$ 2 and a maximum value of $\sim$ 3.5). Photochemical aging processes lead to internal mixing and a larger coating fraction that enhances the light-absorbing capacity of BC particles (Lack and Cappa, 2010). Our finding of the growth of $E_{\mathrm{abs}}$ associated with the increasing ${\mathrm{O}}_x$ concentration suggests that secondary organic aerosol (SOA) includes light-absorbing organic compounds (BrC) (Xu et al., 2016), and that BrC's overall contribution to particle absorption grows under more oxidizing conditions. As discussed in the next section, we find an increase in the imaginary part of the complex refractive index (CRI) of the coated shell.

Scatter plot of $E_{\mathrm{abs}}$ and $\mathit{\omega }$ for different photochemical oxidant concentrations. Variation in the observed diurnally averaged absorption enhancement and SSA (solid points, colour-coded with respect to the concentrations of ${\mathrm{O}}_x$) is used for the modelling constraint. Both $E_{\mathrm{abs}}$ and $\mathit{\omega }$ increase with ${\mathrm{O}}_x$ mixing ratio. The open circles are the single-particle Mie theory calculation results with an optimized BC core size of 160 nm. The CRI of BC was fixed at 1.85 $+$ $i$ 0.71. The real part of the CRI of the coating material was fixed at 1.55. The changes in the imaginary part of the CRI and the thickness of the coating material were colour-coded and shown as the different dimensions (open circle).

[Figure omitted. See PDF]

Coating absorption and light absorption enhancement

Mie theory, which was treated as the basis of the IPCC 5th assessment report due to its computational efficiency and applicability to radiative transfer models (Jo et al., 2017), is a powerful tool for optical data interpretation (Lack et al., 2012) and the reliability of the core–shell model has been verified in many optical closure studies (Lack et al., 2012; Ma et al., 2012; S. Liu et al., 2015; C. Wu et al., 2018). According to Peng et al.'s (2016) chamber study results, BC particles change to a fully compact spherical morphology in less than 1 day. Volatility measurements and analysis of the air masses indicated that the atmospheric aerosol observed in summer at the rural site was well aged. In this work, the particle size distribution information was not available. A method based on single-particle core–shell Mie theory (Bohren and Huffman, 1983; Saleh et al., 2015) was developed to interpret the observed changes in $E_{\mathrm{abs}}$ associated with ${\mathrm{O}}_x$ in this work. The sensitivity of this assumption is discussed in Sect. S7 in the Supplement. The modelling was based on simultaneous constraining of $E_{\mathrm{abs}}$ and SSA to retrieve the fraction contribution of BC absorption ($f_{\mathrm{BC}}$), lensing-driven enhancement ($f_{\mathrm{Lens}}$), coating absorption ($f_{\mathrm{Shell}}$), as well as the coated shell diameter ($D_{\mathrm{Shell}}$) and the imaginary part of the CRI of the shell ($k_{\mathrm{Shell}}$).

A scatter plot of measured diurnally averaged $E_{\mathrm{abs}}$ and SSA for different photochemical oxidant concentrations is shown in Fig. 8. The solid points are the observed results and colour-coded with respect to the concentrations of ${\mathrm{O}}_x$. The open circles are the single-particle Mie core–shell modelled results with an optimized BC core size of 160 nm and colour- and size-coded with respect to the imaginary part of the CRI of coating material ($k_{\mathrm{shell}}$) and the diameter of coating material ($D_{\mathrm{shell}}$), respectively. The colour-coded plot shows the connection between $E_{\mathrm{abs}}$, SSA, and atmospheric photochemistry. The modelled results are consistent with the observed results. Both SSA and $E_{\mathrm{abs}}$ values rise with increasing $D_{\mathrm{shell}}$ and $k_{\mathrm{shell}}$, indicating that the coating thickness and absorption play key roles in determining SSA and $E_{\mathrm{abs}}$. Both $E_{\mathrm{abs}}$ and SSA increased under more oxidizing conditions. This can be explained by the photochemical production of coating species: with more intense photochemical aging, the fraction of internally mixed BC particles and coating thickness increased. Thickly coated BC was also observed by Q. Wang et al. (2017) under higher ${\mathrm{O}}_x$ mixing ratios.

The retrieved diurnal variations in the (b) coating thickness ($D_{\mathrm{Shell}}$) and (c) imaginary part of the CRI ($k_{\mathrm{Shell}}$) of the coated materials, and (d) the relative contribution of the absorption of BC ($f_{\mathrm{BC}}$), lensing effect ($f_{\mathrm{Lens}}$), and absorption of the shell ($f_{\mathrm{Shell}}$). Broadly similar patterns were observed for $D_{\mathrm{Shell}}$, $k_{\mathrm{Shell}}$, $f_{\mathrm{Shell}}$, and (a) ${\mathrm{O}}_x$ concentrations.

[Figure omitted. See PDF]

The corresponding Mie theory calculation results are shown as open circles in Fig. 8 (with further details in Sect. S7 in the Supplement). Comparisons of modelling and observation $E_{\mathrm{abs}}$ and SSA are shown as a scatter plot in Supplement Fig. S12. By fixing the BC core diameter, we can retrieve information on the coating shell ($D_{\mathrm{Shell}}$, $k_{\mathrm{Shell}}$) and each contribution to light absorption ($f_{\mathrm{BC}}$, $f_{\mathrm{Lens}}$, $f_{\mathrm{Shell}}$) under different oxidant conditions (Lack and Cappa, 2010), as shown in Fig. 9. The retrieved D${}_{\mathrm{shell}}$ ranged from 386 to 440 nm. The corresponding D${}_{\mathrm{shell}}$ $/$ D${}_{\mathrm{core}}$ ratio ranged from 2.41 to 2.75, within the range of values (2–4) reported by C. Wu et al. (2018). The plot of measured and modelled $E_{\mathrm{abs}}$ with different $D_{\mathrm{shell}}$ $/$ $D_{\mathrm{core}}$ is shown in the Supplement Fig. S13. The values of $k_{\mathrm{shell}}$ ranged from 0.004 to 0.008 with a diurnal average value of 0.006 ($\pm$0.001). A comparison of the retrieved $k_{\mathrm{shell}}$ with previously reported $k$ values of fresh and aged organic materials is shown in Supplement Fig. S14, which includes BC, BrC aerosol production from biomass burning (BB), atmospheric humic-like substances (HULISs), Suwannee River fulvic acid aerosol (SRFA), and secondary organic material (SOM) produced by photo-oxidation of anthropogenic and biogenic organic precursors. The value of $k_{\mathrm{shell}}$ reported here is comparable with those of BB aerosols (Chakrabarty et al., 2010) and SRFA (Bluvshtein et al., 2016), and is larger than those of SOM (Liu et al., 2013; P. Liu et al., 2015), HULIS (P. Liu et al., 2015) and urban BrC (Cappa et al., 2012).

The retrieved diurnal variations in coating shell ($D_{\mathrm{Shell}}$, $k_{\mathrm{Shell}}$) and the fractional contribution to light absorption ($f_{\mathrm{BC}}$, $f_{\mathrm{Lens}}$, $f_{\mathrm{Shell}}$) are shown in Fig. 9. Broadly similar patterns were observed for $D_{\mathrm{Shell}}$, $k_{\mathrm{Shell}}$, and $f_{\mathrm{Shell}}$ with ${\mathrm{O}}_x$. $D_{\mathrm{Shell}}$ and $E_{\mathrm{abs}}$ tended to be lower in early morning and evening, which was in accordance with anthropogenic activity (with a high CO concentration, as shown in Fig. 5). Peak values of $D_{\mathrm{Shell}}$, $k_{\mathrm{Shell}}$, and $f_{\mathrm{Shell}}$ appeared in the mid-afternoon, which corresponded to a more intense photochemical processing and extensive secondary aerosol generation and resulted in a thicker and more absorbing coating shell. The fractional contribution of $f_{\mathrm{BC}}$, $f_{\mathrm{Lens}}$, and $f_{\mathrm{Shell}}$ ranged from 35 % to 49 %, 35 % to 42 %, and 11 % to 30 %, respectively, with a mean value of 43 % $\pm$ 4 %, 39 % $\pm$ 2 %, and 18 % $\pm$ 5 %. A ternary plot is shown in the Supplement Fig. S15. Our results suggest that the contribution of the lensing effect to absorption enhancement is limited (Bond and Bergstrom, 2006). The lensing effect is reduced due to the greater absorption of the shell (Lack and Cappa, 2010). The change in optical properties at higher oxidant conditions implies a non-negligible contribution of absorbing secondary aerosol material to photochemistry and should receive more attention in climate modelling (Jo et al., 2016).

Conclusions

In this work, the size-resolved mixing state of atmospheric BC particles, light absorption enhancement, and SSA at $\mathit{\lambda }$ $=$ 532 nm was measured at a rural site in east China in the summer of 2016. The volatility measurement shows that atmospheric BC particles were well-aged. A single-particle core–shell Mie theory that connected $E_{\mathrm{abs}}$ and SSA was developed to interpret the observation. Although further improvements of the calculation with size-distributed BC core and coated shell may give a more complete model, the model used currently with a fixed BC core diameter was found to be useful in illustrating the aging process. In our summertime observations, the increase in $f_{\mathrm{Shell}}$ suggests that photochemistry plays a role in modifying BC absorption and indicates that light-absorbing organic compounds require more attention in climate modelling.