Atmos. Chem. Phys., 16, 1332113340, 2016 www.atmos-chem-phys.net/16/13321/2016/ doi:10.5194/acp-16-13321-2016 Author(s) 2016. CC Attribution 3.0 License.

Xingjun Fan1,2, Siye Wei1,3, Mengbo Zhu1,3, Jianzhong Song1, and Pingan Peng1

1State Key Laboratory of Organic Geochemistry, Guangzhou Institute of Geochemistry, Chinese Academy of Sciences, 510640 Guangzhou, P. R. China

2College of Resource and Environment, Anhui Science and Technology University, 233100 Anhui, P. R. China

3Graduate School of Chinese Academy of Sciences, 100049 Beijing, P. R. China

Correspondence to: Jianzhong Song ([email protected])

Received: 11 May 2016 Published in Atmos. Chem. Phys. Discuss.: 24 May 2016 Revised: 24 August 2016 Accepted: 10 October 2016 Published: 28 October 2016

Abstract. Humic-like substances (HULIS) in smoke ne particulate matter (PM2.5) emitted from the combustion of biomass materials (rice straw, corn straw, and pine branch) and fossil fuels (lignite coal and diesel fuel) were comprehensively studied in this work. The HULIS fractions were rst isolated with a one-step solid-phase extraction method, and were then investigated with a series of analytical techniques: elemental analysis, total organic carbon analysis, UVvis (ultravioletvisible) spectroscopy, excitation emission matrix (EEM) uorescence spectroscopy, Fourier transform infrared spectroscopy, and 1H-nuclear magnetic resonance spectroscopy. The results show that HULIS account for 11.223.4 and 5.3 % of PM2.5 emitted from biomass burning (BB) and coal combustion, respectively. In addition, contributions of HULIS-C to total carbon and water-soluble carbon in smoke PM2.5 emitted from BB are8.021.7 and 56.966.1 %, respectively. The corresponding contributions in smoke PM2.5 from coal combustion are 5.2 and 45.5 %, respectively. These results suggest that BB and coal combustion are both important sources of HULIS in atmospheric aerosols. However, HULIS in diesel soot only accounted for 0.8 % of the soot particles, suggesting that

vehicular exhaust may not be a signicant primary source of HULIS. Primary HULIS and atmospheric HULIS display many similar chemical characteristics, as indicated by the instrumental analytical characterization, while some distinct features were also apparent. A high spectral absorbance in the UVvis spectra, a distinct band at ex/ em 280/350 nm

in EEM spectra, lower H / C and O / C molar ratios, and a

Comprehensive characterization of humic-like substances in smoke PM2.5 emitted from the combustion of biomass materials and fossil fuels

high content of [ArH] were observed for primary HULIS.

These results suggest that primary HULIS contain more aromatic structures, and have a lower content of aliphatic and oxygen-containing groups than atmospheric HULIS. Among the four primary sources of HULIS, HULIS from BB had the highest O / C molar ratios (0.430.54) and [HCO] content (1019 %), indicating that HULIS from this source mainly consisted of carbohydrate- and phenolic-like structures. HULIS from coal combustion had a lower O / C molar ratio (0.27) and a higher content of [ArH] (31 %), suggesting that aromatic compounds were extremely abundant in HULIS from this source. Moreover, the absorption ngstrm exponents of primary HULIS from BB and coal combustion were 6.78.2 and 13.6, respectively. The mass absorption efciencies of primary HULIS from BB and coal combustion at 365 nm (MAE365) were 0.972.09 and 0.63 m2 gC1, respectively. Noticeably higher MAE365 values for primary HULIS from BB than coal combustion indicate that the former has a stronger contribution to the light-absorbing properties of aerosols in the atmospheric environment.

1 Introduction

In recent decades, many studies have investigated the water-soluble unresolved polyacidic compounds in atmospheric aerosols, rainwater, and fog/cloud samples (Zheng et al., 2013 and references therein). Due to their similarities to nat-

Published by Copernicus Publications on behalf of the European Geosciences Union.

13322 X. Fan et al.: Comprehensive characterization of humic-like substances

urally occurring humic substances in terrestrial and aqueous environments, with regard to their complex physical and chemical properties, as revealed by techniques such as UV vis (ultravioletvisible) spectroscopy, uorescence spectroscopy, Fourier transform infrared (FTIR) spectroscopy, and nuclear magnetic resonance (NMR) spectroscopy, they are operationally dened as humic-like substances (HULIS;Graber and Rudich, 2006; Zheng et al., 2013). HULIS are present ubiquitously in ne particles from urban, rural, marine, and biomass burning (BB) sources (Decesari et al., 2007; Salma et al., 2007; Lin et al., 2010b; Fan et al., 2012;Song et al., 2012; Zheng et al., 2013). They are believed to play important roles in several atmospheric processes, including light absorption, radiative forcing (Hoffer et al., 2006; Dinar et al., 2008), hygroscopicity, and cloud droplet formation (Dinar et al., 2007; Salma et al., 2008). Moreover, they are also reported to be harmful to human health (Lin and Yu, 2011).

Many eld studies have suggested that HULIS are abundant in organic aerosols. They constitute a signicant portion of the organic matter (OM) in atmospheric aerosols (up to about 30 %) collected in urban and rural environments and in aerosols produced by BB (Mayol-Bracero et al., 2002; Krivacsy et al., 2008; Lin et al., 2010a, b). Their carbon (C) mass accounts for 972 % of the C content of water-soluble organic matter (WSOM) in atmospheric aerosols (Feczko et al., 2007; Krivacsy et al., 2008; Lin et al., 2010b; Fan et al., 2012; Song et al., 2012). These atmospheric HULIS materials are found ubiquitously in various environments, and are derived from various sources. Their possible sources include biomass burning (BB; Feczko et al., 2007; Baduel et al., 2010; Lin et al., 2010a), vehicular emissions (El Haddad et al., 2009), marine emissions (Krivacsy et al., 2008), the oxidation of soot (Decesari et al., 2002; Li et al., 2013, 2015), and secondary processes via the transformation of gas- and condensed-phase species by chemical reactions (Salma et al., 2007; Baduel et al., 2010; Salma et al., 2013).

Among the various sources listed above, BB is generally considered to be a signicant source of atmospheric HULIS (Schmidl et al., 2008a, b; Goncalves et al., 2010; Lin et al., 2010a, b). HULIS fractions have been found in smoke particles emitted from the combustion of wood and leaves; the carbon content of HULIS (HULIS-C) makes up 0.621.2 % of the total mass of particles (Schmidl et al., 2008a, b; Goncalves et al., 2010). HULIS have also been found to be abundant in fresh burning emissions from rice straw and sugar cane leaves (Lin et al., 2010a, b). HULIS accounted for7.612.4 % of the particle mass, and HULIS-C contributed approximately 14.314.7 and 3033 % of the organic carbon (OC) and the water-soluble carbon (WSOC), respectively.Unfortunately, these studies have only focused on the amount of HULIS emitted from BB, with their chemical properties and structures remaining unresolved.

In one recent study, the chemical and light absorption properties of HULIS in ne particulate matter (PM2.5) from

burning of three different types of biomass burning fuels (rice straw, pine needles, and sesame branch) in a laboratory combustion chamber were investigated by Park and Yu (2016).According to this study, primary HULIS from BB accounted for 15.329.5 % of PM2.5 emissions, and HULIS-C contributed 1529 of OC and 3663 % of WSOC, respectively.Although the study brought a better understanding of light absorption properties of primary WSOC from BB, the observations of the optical and structural features of primary HULIS are limited (Park and Yu, 2016). On the other hand, as important energy resources, fossil fuels (such as coal, and diesel fuel) are consumed signicantly around the world, and are known to be important sources of black carbon in ambient aerosols (Cao et al., 2006). However, the contents and chemical properties of primary HULIS from fossil fuels combustion are still unknown.

In this study, smoke PM2.5 emitted from the combustion of biomass materials (including rice straw, corn straw, and pine branch) and fossil fuels (including lignite coal and diesel fuel) were collected in a laboratory chamber. The HULIS fractions were isolated from smoke PM2.5 by a solid-phase extraction (SPE) method, and the chemical properties and structures were comprehensively investigated using total organic carbon (TOC) analysis, elemental analysis, UV vis spectroscopy, excitationemission matrix (EEM) uorescence spectroscopy, FTIR spectroscopy, and 1H-NMR spectroscopy. To further understand the contributions of primary HULIS to atmospheric HULIS, the HULIS fractions isolated from ambient PM2.5 collected in Guangzhou, China, were simultaneously studied and compared with the above primary HULIS. Moreover, the results obtained were also compared with those reported in the literature for HULIS in various atmospheric environments. The information obtained will enable a better understanding of the chemical nature, as well as the environmental, health, and climate effects of primary HULIS from direct combustion emissions, and their contribution to atmospheric HULIS.

2 Experimental

2.1 Sampling

In this study, ve types of smoke PM2.5 samples were collected to investigate the primary HULIS emitted from the combustion of biomass materials and fossil fuels. These were biomass smoke PM2.5 samples emitted from the combustion of rice straw, corn straw and pine branch, and coal smoke PM2.5 and diesel soot. Rice straw and corn straw were chosen primarily because rice and corn are the dominant crops in China. The combustion of these crop straws is reported to have an important inuence on the atmospheric aerosol in China (Streets et al., 2003; Zheng et al., 2006). These crop residues are usually burned in open locations by farmers during and after the harvest season, and are also used as cook-

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X. Fan et al.: Comprehensive characterization of humic-like substances 13323

Table 1. Proximate analysis of three biomass materials and two fossil fuels (wt %; n = 4).

Materials Moisture (%) C (%) H (%) N (%) S (%) O (%)

Rice straw 5.8 0.5 36.0 1.0 5.4 0.5 0.6 0.1 0.1 0.0 37.1 1.2

Corn straw 7.4 0.8 38.7 1.7 6.6 0.2 0.5 0.1 0.2 0.1 44.2 0.5

Pine branch 7.6 0.7 44.7 0.3 7.2 0.0 0.2 0.1 0.1 0.0 45.0 0.4

Coal 1.6 0.2 72.6 0.6 4.0 0.4 0.9 0.0 1.7 0.1

Diesel soot 86.5 0.2 1.4 0.1 0.4 0.0 0.8 0.1 9.1 0.2

ing fuels in rural areas throughout the year. In addition, pine branches are also important biomass cooking fuel in rural areas of China and therefore may make a signicant contribution to the atmospheric aerosol in some regions. Therefore, samples of the smoke emitted from the combustion of these three biomass materials were used to study the BB-derived HULIS. Samples of the smoke emitted from the combustion of coal and diesel fuel were also studied in this work. Coal was chosen because it has been reported that more than 68 % of black carbon (BC) emissions in China are related to the use of coal (Cao et al., 2006). The combustion of coal is an important source of atmospheric aerosols in China. In addition, the soot particles derived from the combustion of diesel fuel was also studied because vehicular emissions have been suggested to be a possible source of atmospheric HULIS (El Haddad et al., 2009).

The biomass materials including rice straw, corn straw, and pine branches were collected from rural areas of Guangdong province, and the coal (the vitrinite reectance (Ro) is

0.77 %) was obtained from Ping Ding Shan, China. Detailed information on this type of coal can be found in Huang et al. (2014). The ultimate properties of the three biomass materials and coal are shown in Table 1. On an air-dried basis, moisture content measured for the rice straw, corn straw, pine branch, and coal was 5.8 0.5, 7.4 0.8, 7.6 0.7,

and 1.6 0.2 %, respectively. Carbon (C), hydrogen (H), and

oxygen (O) contents were found to range from 36.0 to 72.6,4.0 to 7.2, and 8.2 to 45.0 % for combustion materials, respectively. In comparison with biomass materials, coal was substantially composed of higher C content (72.6 %) and lower O content (8.2 %). There were no signicant differences among biomass materials in terms of elemental compositions.

In this study, samples of the smoke PM2.5 emitted from the combustion of rice straw, corn straw, pine branch, and lignite coal were collected in a laboratory resuspension chamber. This sampling system included a combustion stove and two PM2.5 samplers (Tianhong Intelligent Instrument Plant,

Wuhan, China). The instrument is described in detail in Duan et al. (2012). The combustion experiments of biomass fuels (rice straw, corn straw, and pine branch) were carried out in the open air without any controlled conditions to simulate open burning in the eld. Smoke PM2.5 samples were collected on Whatman quartz lters ( 90 mm) by two samplers

in the chamber. For each biomass combustion experiment, biomass materials were rst cut into pieces, and then were ignited and burned out, and one set of two smoke PM2.5 lters was collected during whole burning process (5 15 min).

In total, ve sets of lters samples were collected for each biomass fuel. The coal combustion was carried out according to the method introduced by Huang et al. (2014). The combustion stove was put into the chamber when the combustion condition was stabilized, and then one set of smoke PM2.5 sample was collected for approximately 10 min, and a total of ve sets of lter samples was obtained. For soot, a reference sample (SRM 2975) from the combustion of diesel fuel was purchased from the US National Institute of Standards and Technology (Gaithersburg, MD, USA). It was emitted from a heavy-duty diesel engine, and represents diesel fuel combustion from a vehicular exhaust.

In addition to the smoke PM2.5 samples emitted directly from the combustion process, ambient PM2.5 samples were also collected during 7 to 11 December 2015 in Wushan, Guangzhou, China. Each sample was collected for approximately 24 h, and a total of ve lters was obtained. Detailed information regarding the sampling sites is provided in our previous studies (Fan et al., 2012; Song and Peng, 2009).These PM2.5 samples were collected on Whatman quartz ber lters (20.3 25.4 cm) using a high-volume air sampler

at ow rates of 1.05 m3 min1 (Tianhong Intelligent Instrument Plant, Wuhan, China). All lters had been prebaked at 450 C for 4 h to remove all organic contaminants.

2.2 Isolation of HULIS

In this study, to obtain accurate results for total carbon (TC), HULIS, WSOM, and other parameters, ve lters for each type of sample were selected for analysis. The isolation of HULIS was performed by a one-step SPE procedure, which was applied by many studies (Kiss et al., 2002;Lin et al., 2010a, b; Fan et al., 2012; Park and Yu, 2016).Briey, 3 cm2 lter samples were ultrasonically extracted with 40 mL of 18.2 M[Omega1] Milli-Q water, and then the extract solutions were ltered with polytetrauoroethylene (PTFE) membranes (pore size: 0.22 m) to remove solid impurities and lter debris. The pH value of the ltrate was adjusted to 2 with HCl, and then 20 mL was introduced into a preconditioned SPE cartridge (Oasis HLB, 500 mg, Waters, Mil-ford, MA, USA). The exposed column was rinsed with wa-

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The elemental analyzer was calibrated with an acetanilide standard. Based on the analyses of triplicates for each sample, the calculated relative standard deviation was less than 3 %. The O content was calculated as the rest of the mass, by assuming that the concentrations of other possible elements (e.g., sulfur, phosphorus) were negligible: O % = 100 (C+H+N) %.

2.3.3 UVvisible spectroscopy

About 3 mL of HULIS and WSOM solution was placed in a 1 cm quartz cuvette and scanned from 200 to 700 nm using a UVvis spectrophotometer (Lambda 850, Perkin Elmer, Waltham, MA, USA). Milli-Q water was used as a blank reference and to obtain the baseline. The absorption at 250 nm (UV250), the absorption index, and light absorption properties were determined to characterize the optical properties of HULIS. They are described as follows.

1. The absorption at 250 nm (UV250):

As demonstrated by many studies, the high absorbing UV chromophoric compounds (strong absorbing at 250 nm) are major components in WSOM, which usually tended to be enriched in the SPE isolated HULIS fractions (Baduel et al., 2009; Fan et al., 2012, 2013, 2016; Song et al., 2012; Duarte et al., 2015; Lopes et al., 2015). Therefore, the ratio between the UV250 of HULIS and original WSOM has been widely used to evaluate the relative contribution of HULIS to WSOM in terms of chromophoric compounds content. It should be noted that the HULIS solution must keep the same volume as the original WSOM solution for the UV250 determination.

2. Absorption index:

The specic UVvis absorbance at 254 nm, which is normalized by dissolved organic carbon (DOC) of solution, and absorptivity ratios between 250 and 365 nm (E250 / E365) have been successfully applied to characterize the chemical properties of HULIS and WSOC.They are also determined in this work, and the details can be found in our previous studies (Fan et al., 2012, 2016).

3. Light absorption properties:

HULIS have been proven to have strong wavelength dependence, with absorption increasing sharply from the visible to UV ranges (Hecobian et al., 2010; Park and Yu, 2016). In this study, the absorption ngstrm exponent (AAE) and the mass absorption efciencies at 365 nm (MAE365) were calculated based on UVvis spectroscopy analysis to investigate the light absorption properties of HULIS samples.

AAE is a measure of the spectral dependence of light absorption from chromophores in HULIS. In this study, the

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13324 X. Fan et al.: Comprehensive characterization of humic-like substances

ter to remove inorganics and was dried in a freeze dryer. Finally, the retained organics were eluted with methanol, and the eluate was evaporated to dryness under a gentle nitrogen stream. According to the requirements of TOC, UVvis spectroscopy, and EEM uorescence spectroscopy analysis, the resulting HULIS samples were redissolved in 20 mL of Milli-Q water. Moreover, more area of the corresponding lters was used to obtain enough dried HULIS for the analysis of the elemental composition, as well as FTIR and 1H NMR

spectrometry.

It is noted that the eluates here represent the hydrophobic portion of WSOM and were named as water-soluble HULIS.According to the literature (Graber and Rudich, 2006; Zheng et al., 2013), these water-soluble hydrophobic WSOM can be isolated with different SPE methods. In spite of some differences that were observed among of them, this hydrophobic WSOM isolated with different sorbents is very similar in chemical composition and properties according to our previous studies (Fan et al., 2012, 2013). Therefore, for better comparison with other studies, the hydrophobic WSOM isolated by SPE methods (i.e., HLB, C-18, DEAE, XAD-8) and other protocols (i.e., ELSD) is all termed as HULIS in this paper.

2.3 Analysis

2.3.1 Total carbon (TC) and TOC analysis

The TC content of smoke PM2.5 was measured directly on 2 cm2 punches of the particle lters using an elemental analyzer (Elementar Vario EL CUBE, Hanau, Germany), following a standard high-temperature combustion procedure.A replicate analysis was also conducted for accuracy. The TOC in HULIS and WSOM was measured using a high-temperature catalytic oxidation instrument (Shimadzu TOCVCPH analyzer, Shimadzu, Kyoto, Japan) following the nonpurgeable organic carbon protocol. The concentrations of all chemically measured species were corrected for their respective blank concentration.

2.3.2 Elemental composition

Elemental composition (C, H, N) of the isolated HULIS was measured with an elemental analyzer following a standard high-temperature combustion procedure. A portion of the HULIS (redissolved in methanol) was transferred into a precleaned tin capsule of known weight. Then, the sample was dried in a vacuum. The mass of the dried organic matter (OM) in the tin capsule was determined using a microbalance, with a resolution of 0.01 g (Sartorius, Gttingen, Germany), and then the tin capsule was placed into the elemental analyzer. In the instrument, the C, H, and N content of the OM was determined by catalytic burning in oxygen at 1020 C, followed by chromatographic separation of the oxidation products and thermoconductivity detection.

X. Fan et al.: Comprehensive characterization of humic-like substances 13325

AAEs were calculated based on the linear regression t of logarithms of A and wavelengths between 330 and 400 nm, according to the following power law equation:

A = K AAE,

where A is the absorbance derived from the spectrophotometer at a given wavelength , and K is a constant.

MAE (m2 g 1) is a key parameter that describes the light-absorbing ability of different chromophores. In this study, the MAE at 365 nm (MAE365) was used to characterize the light-absorbing ability for HULIS, and was calculated using the following Eq. (2):

MAE =

3 Results and discussion

3.1 The abundance of HULIS in smoke PM2.5 and ambient PM2.5

The average abundance of the HULIS fractions and their contributions to particle matter (PM), TC, and WSOM in smoke PM2.5 emitted from the combustion of biomass materials, fossil fuels, and in ambient PM2.5 are shown in Table 2. It can be seen that the mass of the HULIS fractions accounted for 11.223.4 % of the PM in smoke PM2.5 emitted from BB, which is comparable to the results (7.629.5 %) for BB reported in previous studies (Lin, 2010b, Park and Yu, 2016). It is worth noting that the highest HULIS abundance (23.4 5.5 %) was detected in rice straw smoke

PM2.5, which is consistent with 29.5 % for similar samples observed by Park and Yu (2016). However, it is approximately double the 12.4 % reported for similar samples by Lin et al. (2010b), which may be ascribed to their different combustion conditions and sampling methods. The abundance of HULIS in rice straw smoke PM2.5 (23.4 5.5 %)

was also signicantly higher than in ambient PM2.5 in this study, and in some previous studies (as listed in Table 2).The abundance of HULIS in smoke PM2.5 emitted from the combustion of corn straw and pine branch (11.2 7.5 and

11.4 3.8 %, respectively) was signicantly lower than in

smoke PM2.5 from rice straw. This was similar to the results for ambient PM2.5 in this study and values reported by Lin et al. (2010b), although they were higher than the 6.7 % reported by Salma et al. (2007) and an annual observation(5.4 %) in the same location, reported in our previous study (Fan et al., 2016).

In comparison with the three BB smoke PM2.5 samples, the relative contribution of HULIS in coal smoke PM2.5 was relatively low (5.3 0.4 %). This was signicantly lower

than the level in PM2.5 in this study and that reported by Lin et al. (2010), but was similar to the annual average result(5.4 %) for ambient PM2.5 in our previous study (Fan et al., 2016). According to data reported by Cao et al. (2006), more than 68 % of BC emissions in China are related to the use of coal. Therefore, it is expected that coal combustion is an important primary source of atmospheric HULIS. It is noteworthy that HULIS only accounts for 0.8 % of diesel soot,

suggesting that the primary source of atmospheric HULIS from vehicle exhaust may be negligible. Because the abundance of HULIS in diesel soot was so low, it was difcult to characterize this HULIS fraction.

As an important carbonaceous component, the C content of HULIS (HULIS-C) in smoke PM2.5 particles emitted from the combustion of rice straw, corn straw, and pine branch accounted for 21.7 4.0, 14.7 6.9, and 8.0 2.9 %

of the TC, respectively. These results are very consistent with the results reported for BB in previous studies (Schmidl et al., 2008a, b; Goncalves et al., 2010; Lin et al., 2010b; Park and Yu, 2016). The HULIS-C in coal smoke

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A

C L

ln(10),

where C is the DOC content of HULIS in solution (ugC mL1), and L is the optical path length (0.01 m).

2.3.4 EEM uorescence spectroscopy

The uorescence spectra of each HULIS sample were recorded on a spectrophotometer (F-2700, Hitachi, Tokyo, Japan), using a 1 cm path-length quartz cuvette. Excitation and emission wavelength ranges were set from 210 to 400 and 230 to 510 nm, respectively, and their scanning intervals were all set at 5 nm. The excitation and emission slit widths were xed at 5 nm, and the scan speed was set at 1500 nm min1. The peaks due to water Raman scatter were eliminated from all sample EEMs by subtracting the Milli-Q water blank EEMs.

2.3.5 FT-IR spectrometry

The FTIR spectra (4000400 cm1) of HULIS were recorded at room temperature using an FTIR spectrometer (Vertex-70, Bruker, Mannheim, Germany). About 1 mg of HULIS (redissolved in methanol) was rst mixed with 60 mg of KBr, and then dried in a freeze dryer. Finally, the above mixture was grated and pressed into pellets for analysis. For each measurement, 64 scans were collected at a resolution of 2 cm1.

2.3.6 1H-NMR spectroscopy

About 10 mg of dried HULIS was dissolved in deuterated methanol (MeOH-d4, 1 mL) and transferred to 5 mm NMR tubes. The 1H NMR spectra of HULIS were recorded on a 400 MHz NMR spectrometer (Avance III, Bruker). For each sample, 128 scans were collected, resulting in an analysis time of approximately 1 h. The identication of functional groups in the NMR spectra was based on their chemical shift ( H) relative to that of sodium 3-trimethylsilyl-2,2,3,3-d4-propanoate ( H= 0 ppm), which was used as an internal stan

dard.

13326 X. Fan et al.: Comprehensive characterization of humic-like substances

Table 2. The contributions of HULIS to particular matter (PM), total carbon (TC), and water-soluble organic matter (WSOM) in smoke PM2.5 emitted from combustion of biomass materials and fossil fuels, and in ambient PM2.5.

Samples Types Isolation HULIS-C/PM HULIS/PM HULIS-C/OC HULIS-C/TC HULIS/WSOM HULIS/WSOM References methods (gC g1, %) (%) (%) (%) (TOC, %) (UV250, %)

Rice straw Smoke PM2.5 (n = 5)

a HLB 13.5 3.1 23.4 5.5

b 21.7 4.0 66.1 2.4 79.5 1.5 Present work

Corn straw Smoke PM2.5 (n = 5) HLB 5.9 4.0 11.2 7.5

b 14.7 6.9 59.2 2.4 75.4 2.9

Pine branch Smoke PM2.5 (n = 5) HLB 6.4 2.2 11.4 3.8

b 8.0 2.9 56.9 3.1 68.1 5.5

Coal Smoke PM2.5 (n = 5) HLB 3.5 0.3 5.3 0.4

b 5.2 0.3 45.5 2.1 64.4 3.9

Diesel soot SRM 2975 (n = 5) HLB 0.5 0.01 0.8 0.02

c 0.7 0.0 62.3 3.7 58.3 3.5

Urban aerosols PM2.5 (n = 5) HLB 5.2 0.4 10.7 0.8

b 26.8 3.3 22.6 3.7 60.7 1.0 70.7 2.1

Leaf Smoke PM10 C18-SAX 18.521.2 33.034.5 27.831.3 Schmidl et al. (2008a) Wood Smoke PM10 C18-SAX 0.65.8 1.012.0 0.99.2 Schmidl et al. (2008b)

Wood Smoke PM10 C18-SAX 1.52.4 3.511.5 2.85.3 Goncalves et al. (2010) Sugarcane Smoke PM2.5 ELSD 7.6 14.3 33 Lin et al. (2010b)

Rice straw Smoke PM2.5 ELSD 12.4 14.7 30 Lin et al. (2010b) Rice straw Smoke PM2.5 HLB 15 1 29.5 2.0 26 3 24.2 63 5 Park and Yu (2016)

Pine needles Smoke PM2.5 HLB 8 3 15.3 3.1 15 4 14.9 36 8 Park and Yu (2016)

Sesame stems Smoke PM2.5 HLB 13 4 25.8 4.0 29 8 28.3 51 8 Park and Yu (2016)

Vehicular exhaust PM2.5 DEAE 0.6 2.9 1.0 18.4 I.El Haddad et al. (2009) Vehicular exhaust PM10 DEAE 0.8 3.4 1.3 20.7 I.El Haddad et al. (2009)

Roadway site aerosols PM2.5 XAD7 HP 5.2 34.5 26.6 59.8 Park et al. (2013) Marine aerosol PM10 HLB 12 19 Krivacsy et al. (2008)

Rural aerosols PM1.5 HLB 39 57 Kiss et al. (2002) Rural aerosols PM2.5 XAD-8 4.3 23.2 19.5 51.9 Duarte et al. (2007)

Urban aerosol PM2.5 ELSD 6.0 11.7 29.5 60 Lin et al. (2010b) Urban aerosol PM2.5 HLB 6.7 18.3 10.6 62 Salma et al. (2007)

Urban aerosol PM2.5 HLB 26.628.9 18.420.8 45.849.7 Salma et al. (2008) Urban aerosol PM2.5 XAD7HP 35.4 27.6 63.0 Park et al. (2012)

Urban aerosol (dust) PM2.5 XAD7HP 6.2 31.4 24.6 71.9 Park and Cho (2013) Urban aerosols PM2.5 ENVI-18 2.8 1.3 5.4 2.7 16.9 4.9 13.0 4.5 49.5 5.9 68.3 4.7 Fan et al. (2016)

a Indicating the number of replicates of samples. b HULIS mass is calculated by OM / OC ratios obtained by elemental analysis listed in Table 3. c HULIS mass is calculated by the OM / OC ratio (1.51) of primary HULIS in coal smoke PM2.5.

Table 3. Elemental composition and molar ratios of HULIS in smoke PM2.5 from combustion of rice straw, corn straw, pine branch, and coal, and in ambient aerosols.

Elemental composition (%) Molar ratios

Samples Types Isolation methods N C H Oa H / C O / C N / C OM / OCb References

Rice straw Smoke PM2.5 HLB 4.1 57.4 5.5 33.0 1.15 0.43 0.06 1.74 Present work Corn straw Smoke PM2.5 HLB 2.5 52.9 6.3 38.3 1.43 0.54 0.04 1.89

Pine branch Smoke PM2.5 HLB 2.0 56.7 6.6 34.7 1.40 0.46 0.03 1.77 Coal Smoke PM2.5 HLB 3.3 66.1 7.1 23.6 1.28 0.27 0.04 1.51

Urban aerosols PM2.5 HLB 2.9 48.5 6.4 42.1 1.59 0.65 0.05 2.06

Alpine aerosol PM2.5 C-18 2.5 52 6.7 38 1.53 0.55 0.04 1.91 Krivacsy et al. (2001) Rural aerosol PM1.5 HLB 2.5 52 6.2 39 1.43 0.58 0.04 1.93 Kiss et al. (2002)

Rural aerosol PM2.5 XAD-8 2.13.8 5158 5.66.5 3237 1.211.42 0.410.55 0.030.06 1.711.95 Duarte et al. (2007) Urban aerosol PM2.5 HLB 3.1 55 7 35 1.49 0.47 0.05 1.82 Salma et al. (2007)

Urban aerosol TSPc HLB 2.03.9 4353 4.46.9 3844 1.071.9 0.550.76 0.030.07 1.892.28 Song et al. (2012) Urban aerosol PM2.5 HLB 3.1 54 5.9 38 1.31 0.53 0.05 1.86 Fan et al. (2013)

Urban aerosol PM2.5 DAX-8 2.32.6 60.465.7 5.616.08 25.931.2 1.011.15 0.300.39 0.030.04 1.51.7 Duarte et al. (2015)

a Calculated as O % = 100 (C+H+N) %.

b Calculated as OM to OC mass ratios. c total suspended particulate.

PM2.5 was 5.2 0.3 %, which was signicantly lower than

that (22.6 3.7 %) in ambient PM2.5. The contribution of

HULIS-C to the TC of diesel soot was about 0.7 %, which was similar to the 1.01.3 % reported for vehicular exhaust in El Haddad et al. (2009). These very low HULIS-C/TC ratios also suggest that the primary vehicular exhaust source for atmospheric HULIS may be negligible.

It is well known that HULIS is an important component in WSOC. In this study, the contribution of HULIS to WSOC was investigated by the determination of TOC and UV250, respectively. As indicated in Table 2, the HULIS/WSOM ratios in the ve types of smoke PM2.5 were 45.566.1 %

(TOC, %) and 58.379.5 % (UV250, %), indicating that HULIS was the major component in WSOM for the samples studied here. These percentages lie within the range of

1972 % that has been reported for ne aerosols in many earlier studies (as listed in Table 2). Although relatively high HULIS/WSOM ratios were observed for all of the different smoke PM2.5, some differences were apparent. The

HULIS/WSOM for the three types of biomass smoke PM2.5 was 56.966.1 and 68.179.5 %, as determined by TOC and UV250, respectively. They are similar to the values obtained for atmospheric HULIS in this study, at 60.7 and 70.7 %, respectively. These results are also comparable with those reported for ambient aerosols (Zheng et al., 2013 and references therein). The HULIS/WSOM was relatively low for coal smoke PM2.5, at 45.5 and 64.4 %, as determined by TOC and UV250, respectively. For the diesel soot, despite the very low HULIS-C/TC, the HULIS/WSOM for diesel soot was relatively high, at 62.3 and 58.3 %, as determined by TOC

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Figure 1. The normalized UVvis spectra with TOC (units: cm2 mgC1) of HULIS in smoke PM2.5 from combustion of rice straw, corn straw, pine branch, and coal, and in ambient PM2.5.

and UV250, respectively. It should be noted that the values of HULIS/WSOM determined by UV250 were mostly higher than those obtained by TOC. These differences have been derived from similar measurement methods, and have been reported in many previous studies (Baduel et al., 2009; Fan et al., 2012), mainly as the result of the enrichment of highly conjugated bond compounds in HULIS fractions. A more detailed explanation is given in Sect. 3.3.

3.2 Elemental composition

The elemental compositions (C, H, N, and O) of HULIS in smoke PM2.5 from the combustion of rice straw, corn straw, pine branch, and coal, and in ambient PM2.5 are shown in Table 3. The mean C, H, N, and O contents for the primary HULIS samples were 52.966.1, 5.57.1, 2.04.1, and 23.638.3 %, respectively, by mass. This indicates the dominance of C and O, which together contributed 89.791.4 % of the total mass. It is obvious that the primary HULIS contain substantially higher C and lower O than ambient HULIS in this study. However, these results are comparable with those for atmospheric HULIS in previous studies (Krivacsy et al., 2001; Kiss et al., 2002; Duarte et al., 2007, 2015; Salma et al., 2007; Song et al., 2012; Fan et al., 2013).

Only a limited amount of information regarding the different HULIS could be obtained from the elemental composition data, but more qualitative information was obtained by an examination of the O / C, H / C, and N / C molar ratios. These atomic ratios are often used to describe characteristic and structural changes of organic macromolecules (Duarte et al., 2007; Salma et al., 2007; Fan et al., 2013). The O / C molar ratios for the primary HULIS ranged from 0.27 to 0.54, indicating the existence of O-containing functional groups. However, these ratios were signicantly lower than 0.610.68 for the standard fulvic acids of the International Humic

Substances Society (Duarte et al., 2007), indicating that primary HULIS was less oxidized when compared to the fulvic acids. Among the four types of primary HULIS, the O / C ratios of the three types from BB were in the range of 0.430.54, which were lower than 0.65 for ambient HULIS in this study, but were comparable with data (0.300.76) for atmospheric HULIS reported in previous studies (Krivacsy et al., 2001; Kiss et al., 2002; Duarte et al., 2007, 2015; Salma et al., 2007; Song et al., 2012; Fan et al., 2013). The O / C ratio of HULIS in coal smoke PM2.5 was 0.27, which was significantly lower than for atmospheric HULIS samples. These results suggest that HULIS in the fresh coal smoke PM2.5 could be regarded as less oxidized than HULIS in ambient aerosols. The H / C molar ratios of the four primary types of HULIS were in the ranges of 1.15 to 1.43, which were lower than that (1.59) for atmospheric HULIS in this work.However, they fell in the range of observations (1.011.53) reported in previous studies (Krivacsy et al., 2001; Kiss et al., 2002; Duarte et al., 2007, 2015; Salma et al., 2007; Song et al., 2012; Fan et al., 2013). The N / C molar ratios of primary HULIS were 0.030.06, with both being similar to the results for atmospheric HULIS in this study and in previous studies (Table 3). In addition, the ratio of OM to organic C (OM / OC) mass ratios of the four types of primary HULIS ranged from 1.51 to 1.89, which were lower than 2.06 for ambient HULIS in this study, but were generally in the range of the data (1.52.28) reported for atmospheric HULIS in previous studies (Krivacsy et al., 2001; Kiss et al., 2002; Duarte et al., 2007, 2015; Salma et al., 2007; Song et al., 2012; Fan et al., 2013).

In summary, the four types of primary HULIS among the smoke PM2.5 samples had many similarities, in terms of its elemental composition, to atmospheric HULIS samples. However, there were also some distinct differences. The HULIS samples in the three types of biomass smoke PM2.5 had a relatively lower C content (52.957.4 %), higher O content (33.038.3 %), higher O / C molar ratio (0.430.54), and higher OM / OC (1.741.89) than those in coal smoke PM2.5. These results indicated that the HULIS in BB smoke contained a relatively higher content of O-containing components. Among the three HULIS in BB smokes, the O / C molar ratios of corn straw HULIS were higher than those of rice straw and pine branch HULIS, indicating that corn straw HULIS contain more O-containing compounds. In terms of H / C molar ratio, HULIS from rice straw and coal combustion exhibit lower values than the other two primary types of HULIS.

3.3 UVvis properties

UVvis absorbance has been widely used to characterize the properties of organic matter in soils, waters, and atmospheric systems. Figure 1 shows the UVvis spectra of the four primary types of HULIS in smoke PM2.5 emitted from BB and coal combustion and one atmospheric HULIS sample from

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ambient PM2.5. The spectra were all normalized by the C content of HULIS to avoid the effects of different concentrations, and were easily compared with each other. As shown in Fig. 1, the UVvis spectra of all HULIS fractions were featureless, while they displayed a generally decreasing absorbance as the wavelength increased. Such spectra are similar to the typical UVvis spectra of atmospheric HULIS in previous studies (Havers et al., 1998; Varga et al., 2001; Kiss et al., 2002; Duarte and Duarte, 2005; Duarte et al., 2005;Krivacsy et al., 2008; Baduel et al., 2009, 2010; Fan et al., 2012) and in naturally occurring humic substances (Traina et al., 1990; Peuravuori and Pihlaja, 1997; Chen et al., 2002;Domeizel et al., 2004). These results suggest that the primary HULIS in smoke PM2.5 have a similar chemical structure to

HULIS in atmospheric aerosols.

Although the spectra appeared to be broad and featureless, some differences in the absorption intensity were apparent.The spectra obtained for the four types of primary HULIS in smoke PM2.5 exhibited a higher normalized absorbance in shorter wavelength regions and less absorbance in the longer wavelength regions than atmospheric HULIS. A clear shoulder in the region 250 to 300 nm was observed in the spectra of primary HULIS fractions in smoke PM2.5 emitted from BB and coal combustion. This is generally attributed to * electron transitions in moieties containing C = C and C = O

double bonds, and is also a characteristic of fulvic acids (Peuravuori and Pihlaja, 1997; Domeizel et al., 2004). These results suggest that the primary HULIS in smoke PM2.5 may contain a higher concentration of polycyclic aromatic and conjugated compounds than ambient HULIS.

Among of the four types of primary HULIS, HULIS in smoke PM2.5 emitted from corn straw burning had a higher normalized UVvis absorbance in the overall spectra than the other primary HULIS fractions. HULIS in coal smoke had a lower normalized absorbance than the other types of primary HULIS, and this was even much lower than that for atmospheric HULIS in the region of 350 to 535 nm, with its absorbance mainly focused in the region of 235 to 385 nm.This may suggest that polycyclic aromatic and/or conjugated compounds are the most important components in this type of HULIS, and this was in strong agreement with the results obtained from the 1H NMR analysis.

The SUVA254 and E250 / E365 have been found to be correlated with aromaticity and molecular weight of natural occurring humic acids (Peuravuori et al., 2001; Fuentes et al., 2006; Chen et al., 2002). They have also been frequently applied to characterize HULIS in atmospheric aerosols (Duarte and Duarte, 2005; Duarte et al., 2005; Krivacsy et al., 2008;Baduel et al., 2009, 2010; Fan et al., 2012). In this study, these parameters were used to perform comparisons between HULIS in smoke PM2.5 and in ambient PM2.5, with the results shown in Table 4. The SUVA254 values of primary smoke HULIS samples ranged from 3.7 to 3.9 L (m mgC)1, which was higher than the value of the atmospheric HULIS fractions obtained in this study and our previous studies (Fan

et al., 2012, 2016). These results indicate that the primary HULIS contain more aromatic groups with conjugation of bonds alongside aliphatic structures. Similar characteristics were also found in many previous studies. For example, it has been found that the HULIS fraction in the colder season presented more aromatic structures than those in the warmer season, of which the BB might be an important contribution of the former one (Baduel et al., 2010; Matos et al., 2015a, b; Paula et al., 2016). Moreover, the E250 / E365 ratios were also investigated, which were found to be 5.8 0.5,

4.5 0.2, 4.4 0.3, and 14.7 0.7 for primary HULIS emit

ted from the combustion of rice straw, corn straw, pine branch, and coal, respectively. The E250 / E365 ratio generally exhibits a negative relationship with the aromaticity or molecular weight of humic-like substances (Duarte and Duarte, 2005; Fan et al., 2012). The E250 / E365 ratios of primary HULIS in smoke PM2.5 from BB were in the range of 4.45.8, which is comparable to that (2.98.9) of atmospheric HULIS here and in previous studies (as listed in Table 4).

There were also some distinct features among the different types of primary HULIS in terms of their UVvis properties.No signicant differences in SUVA254 were identied among the primary HULIS from the combustion of rice straw, corn straw, pine branch, and coal. However, the E250 / E365 ratios of the four types of primary HULIS ranged from 4.4 to 14.7, with the highest values for the HULIS from coal combustion.It was noteworthy that the E250 / E365 ratio of HULIS in coal soot was 14.7, which was much higher than for the HULIS in biomass smoke PM2.5 and in atmospheric PM2.5, but the

SUVA254 value was in a similar range for all of these types of HULIS. Therefore, caution should be exercised when using just the spectra parameter of E250 / E365 for the characterization of HULIS.

3.4 Fluorescence properties

Fluorescence spectroscopy has been used as a technique for classifying and distinguishing between humic substances of various origins and natures. It has been widely applied to characterize HULIS in atmospheric aerosols (Duarte et al., 2004; Santos et al., 2009, 2012). Figure 2 shows the EEM uorescence spectra of HULIS in smoke PM2.5 from BB and coal combustion, and in ambient PM2.5. To avoid concentration effects, the uorescence spectra were normalized by the WSOC content of HULIS, and are shown here as specic uorescence intensities (a.u. L (g C1)).

As shown in Fig. 2, the four types of primary HULIS in smoke PM2.5 have similar uorescence features, with two main types of uorophores at ex/ em (245255)/(420

435) nm (peak A) and ex/ em (265290)/(335370)

(peak B). Bands in the same range as peaks A and B have already been identied in the EEM uorescence spectra of water-soluble organic matter from rainwater (Kieber et al., 2006; Santos et al., 2009, 2012), fog water (Bird-

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Table 4. Absorptivity ratio between 250 and 365 nm (E250 / E365), and the specic UV absorbance at 254 nm (SUVA254) of HULIS in smoke PM2.5 from combustion of rice straw, corn straw, pine branch, and coal, and in ambient PM2.5.

Samples Type Isolation methods E250 / E365 SUVA254 References

Rice straw Smoke PM2.5 HLB 5.8 0.5 3.7 0.5 Present work

Corn straw Smoke PM2.5 HLB 4.5 0.2 3.9 0.7

Pine branch Smoke PM2.5 HLB 4.4 0.3 3.7 0.4

Coal Smoke PM2.5 HLB 14.7 0.7 3.7 0.1

Urban aerosols (fall) PM2.5 HLB 7.2 0.3 2.5 0.1SRFA 4.86 3.94 Fan et al. (2012) Urban aerosols PM2.5 ENVI-18, HLB, XAD-8, and DEAE 4.75.2 2.64.6

Rural aerosols PM2.5 ENVI-18, HLB, XAD-8, and DEAE 5.56.2 2.72.8

Urban aerosols Annual PM2.5 ENVI-18 5.9 0.9 3.2 0.5 Fan et al. (2016) Urban Summer PM10 HLB 7.3, 9.7 Krivacsy et al. (2008)

Urban Winter PM10 HLB 5.6, 5.7Rural aerosols PM1.5 HLB 8.0 Kiss et al. (2002)

Urban aerosols Cold season PM2.5 DEAE 3.13.5 Baduel et al. (2010) Urban aerosols Summer PM2.5 DEAE 4.65.9

Urban aerosols Mid-season PM2.5 DEAE 3.43.6

Biomass burning background aerosols Urban PM2.5 DEAE 2.9 0.2

Rural aerosols Summer PM2.5 XAD-8 8.9 Duarte and Duarte (2005)

Rural aerosols Autumn PM2.5 XAD-8 6.1

Urban/oceanic aerosols PM2.5 XAD-8 5.8

well and Valsaraj, 2010), and atmospheric aerosols (Duarte et al., 2004), and have been assigned to fulvic-like and protein-like uorophores (Kieber et al., 2006), respectively. Our results indicate that the primary HULIS fractions had similar fulvic-like and protein-like organic fractions to atmospheric HULIS (Duarte et al., 2004; Santos et al., 2009, 2012). However some differences in peak A and B were identied between the four types of primary HULIS and the atmospheric HULIS. For peak A, the Ex/Em wavelengths in the EEM uorescence spectra of primary HULIS had peaks at longer excitation and emission wavelengths ( ex/ em (245255)/(420435) nm) than those

( ex/ em 245/405 nm) of atmospheric HULIS. This sug

gests that primary HULIS fractions contain more aromatic structures and condensed unsaturated bond systems, but fewer aliphatic structures (Peuravuori et al., 2002; Duarte et al., 2004; Graber and Rudich, 2006; Krivacsy et al., 2008; Santos et al., 2009). For peak B, the four types of primary HULIS all had a protein-like uorescence band at a similar ex/ em in the EEM uorescence spectra. In all four types of primary HULIS the band was clearly stronger than the band in ambient HULIS described in this study and in previous studies (Duarte et al., 2004; Santos et al., 2009, 2012). This nding indicates that these four types of primary HULIS consist of more phenol-like, protein-like, and/or aromatic amino acids than atmospheric HULIS (Coble, 1996; Peuravuori et al., 2002; Duarte et al., 2004; Kieber et al., 2006).

Compared to the ambient HULIS in this study and in previous studies (Duarte et al., 2004; Santos et al., 2009, 2012), a distinct band at ex/ em 295/405 nm (peak C), which is

generally attributed to humic-like compounds (Coble and

Green, 1990; Coble, 1996), was not present in the EEM uorescence spectra of primary smoke HULIS. This peak C is normally identied in naturally occurring humic acids and atmospheric HULIS, and has been assigned to marine humic-like compounds (McKnight et al., 2001; Duarte et al., 2004; Kieber et al., 2006; Santos et al., 2009, 2012). Peak C only occurred in EEMs of atmospheric HULIS, which suggests that marine sources were also an important contributor to HULIS in atmospheric aerosols in the Pearl River Delta (PRD) region (Lin et al., 2010a; Fan et al., 2016).

3.5 FTIR spectroscopy

The FTIR spectra of the HULIS in smoke PM2.5 emitted from the combustion of rice straw, corn straw, pine branch, and coal, and in ambient PM2.5, were within the region of 40001000 cm1, as shown in Fig. 3. All spectra were characterized by a number of absorption bands, exhibiting variable relative intensities, which is typical of humic(-like) materials (Senesi et al., 1989; Havers et al., 1998; Duarte et al., 2007). As shown in Fig. 3, the spectra of primary HULIS were similar to those of the atmospheric HULIS and WSOM in this study and in previous studies (Havers et al., 1998; Krivacsy et al., 2001; Kiss et al., 2002; Duarte et al., 2005; Polidori et al., 2008; Santos et al., 2009; Fan et al., 2013; Duarte et al., 2015). The interpretation of these spectra was based on the assignments given in the literature referred to above for humic(-like) substances, resulting in the major characteristic bands that are marked in Fig. 3, with the corresponding assignments listed in Table 5.

As shown in Fig. 3, the FTIR spectra of the four types of primary HULIS fractions predominantly exhibit the presence

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Figure 2. EEM spectra of HULIS in smoke PM2.5 from combustion of rice straw (a), corn straw (b), pine branch (c), and coal (d), and in ambient PM2.5 (e), presented as specic intensity (a.u. L (g C1)).

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Table 5. Major band assignments for FT-IR spectra of HULIS in smoke PM2.5 from biomass burning and coal combustion, and in ambient aerosols.

Wave number (cm1) Band assignments

3420 Stretching vibration of OH28502980 Stretching vibrations of aliphatic CH1710 Stretching mainly of carboxyl-C and traces of ketones and esters C = O

1637 Stretching mainly of aromatic C = C and ketones, quinones, and amides C = O

1610 Stretching vibration of aromatic rings 1516 Stretching vibrations of aromatic C = C

1458 Deformation of CH2 and CH3 bending and stretching vibration of aromatic rings 1385 Deformation of aliphatic CH (some CO stretching of phenolic OH)

1278 Stretching of aromatic CO and phenolic OH1220 Stretching vibrations of CO and deformation of carboxylic OH 1115 Stretching of ring breathing CO1045 Stretching of polysaccharide CO or deformation of aromatic CH

Figure 3. FTIR spectra of primary HULIS in smoke PM2.5 from combustion of rice straw (a), corn straw (b), pine branch (c), coal (d), and in ambient PM2.5 (e).

of O-containing functional groups, aliphatic CH groups, and aromatic ring groups, with the majority of the valence vibrations also being characteristics. The broad and strong band centered at around 3420 cm1 is generally attributed to the OH stretching of phenol, hydroxyl, and carboxyl groups. The strong band near 1720 cm1 is usually assigned to C = O

stretching, mainly of carboxyl groups. However, to a lesser extent, ketonic and/or aldehydic C =O groups can also give

rise to absorption near this wave number, and their contribution should not be neglected. Some bands were also displayed near 1458, 1610, and 1637 cm1, indicating the presence of aromatic groups. These results suggest that primary

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13332 X. Fan et al.: Comprehensive characterization of humic-like substances

smoke HULIS are complex compounds, mainly containing aliphatic chains, carboxylic groups, and aromatic groups.These FTIR spectra features are similar to those of the atmospheric HULIS described in this study and in other studies (Krivacsy et al., 2001; Duarte et al., 2005, 2015; Song et al., 2012; Fan et al., 2013).

There were many discriminatory characteristics between primary HULIS and atmospheric HULIS. A relatively weaker band at 1710 cm1 for primary HULIS than for atmospheric HULIS was observed in Figure 3, indicating that the former ones contain fewer carboxyl groups (Song et al., 2012; Fan et al., 2013). The bands at 1458 and 1610 cm1, which are generally attributed to the CC stretching of aromatic rings (Watanabe and Kuwatsuka, 1992; Duarte et al., 2015), are observed in spectra of primary HULIS from direct combustion emissions. However, they were less intense, or even absent in the FTIR spectra of atmospheric HULIS fractions in this study and in some previous studies (Krivacsy et al., 2001; Duarte et al., 2005; Fan et al., 2013). This indicates that more aromatic rings are present in the primary HULIS from BB and coal combustion than in atmospheric HULIS.In addition, the bands near 1516 and 1115 cm1, which are ascribed to the stretching vibrations of aromatic C = C and

CO bonds, were apparent in the spectra of primary HULIS from BB, but absent from the atmospheric HULIS in this study and in some other studies (Santos et al., 2009, 2012;Fan et al., 2013). Because these wave number regions are often typically displayed in the spectra of lignin, they can be used as a marker to reect BB contributions to atmospheric HULIS. For example, this band has been observed in the FTIR spectra of atmospheric HULIS in the fall and winter seasons, when HULIS is likely to be signicantly inuenced by BB (Duarte et al., 2005, 2007). Simultaneously, a relatively strong band at 1045 cm1 was found in the spectra of primary HULIS from BB, which is often attributed to the CO bond stretching of polysaccharides (Havers et al., 1998), and is also a characteristic of BB sources.

There were also some discriminatory differences between the primary HULIS fractions in the minor bands, and in the shape and intensity of the major bands in the 2000 1000 cm1 region of FTIR spectra. As shown in Fig. 3, relatively sharper and stronger peaks at 1637, 1610, 1458, and 1385 cm1 were displayed in the spectra of HULIS fractions in smoke PM2.5 from coal combustion than those from BB.These results indicated that coal smoke HULIS consisted of more aromatic structures. It was noteworthy that additional peaks at 3160 and 1400 cm1 were observed in the spectra of HULIS from the burning of corn straw. They are related to the stretching of CO and OH bonds (Watanabe and Kuwatsuka, 1992; Chen et al., 2002), indicating that there were more oxygenated phenolic structures in the HULIS from corn straw burning. This is consistent with the results derived from the elemental analysis, in which a higher O / C molar ratio was obtained for HULIS from corn straw burning. One distinct feature of the primary HULIS from BB was the oc-

currence of one sharper and stronger peak at 1516 cm1 on the FTIR spectra. This band is generally assigned to stretching vibrations of aromatic C =C bonds and CO bonds, and

is often observed in the spectra of compounds derived from lignin (Watanabe and Kuwatsuka, 1992; Santos et al., 2000;Duarte et al., 2003). Consequently, primary HULIS from BB displayed the characteristic of containing a lignin-like structure in its molecules, which can be seen as an important indicator of a BB source.

3.6 1H-NMR spectroscopy

A critical review on the application of 1H NMR spectroscopy on WSOM in atmospheric aerosols has been presented, in which 1H NMR was demonstrated to be an important and novel tool to characterize WSOM, which can not only provide deep insight into the structural characteristics of them but also reect their sources (Duarte and Duarte, 2015). In this work, 1H NMR was applied to characterize the primary HULIS from BB and coal combustion and atmospheric HULIS. Figure 4 shows the 1H NMR spectra of the four types of primary HULIS in smoke PM2.5 emitted from the combustion of rice straw (a), corn straw (b), pine branch(c), and lignite coal (d), and atmospheric HULIS in ambient PM2.5 (e). The four types of primary HULIS displayed similar spectra to the atmospheric HULIS spectra in this study, which were also comparable to 1H NMR spectra of HULIS and/or WSOM in fog (Decesari et al., 2000), cloud (Decesari et al., 2005), rainwater (Santos et al., 2009, 2012), biomass burning aerosols (Graham et al., 2002), and urban/rural aerosols (Decesari et al., 2007; Ziemba et al., 2011;Song et al., 2012; Fan et al., 2013; Lopes et al., 2015).

As shown in Fig. 4, compared with the atmospheric HULIS, more distinct sharp signals of organic species could be seen in the 1H NMR spectra of primary HULIS. According to the results of Fan et al. (2012), some low molecular weight organic compounds (e.g., suberic, 3,5-dihydroxybenzoic, and phthalic acids) are generally present in isolated HULIS fractions. Thus, these sharp peaks in the

1H NMR spectra of primary HULIS can be ascribed to low molecular weight organic species in the smoke PM2.5. The relatively few and/or weak sharp peaks in the 1H NMR spectra of atmospheric HULIS may be the result of low molecular weight organic compounds that have been removed by oxidation or transformed to HULIS. Among these sharp signals, a limited number of resonances could be attributed to specic organic species by comparison with previous studies (Decesari et al., 2000, 2001; Suzuki et al., 2001; Matta et al., 2003; Cavalli et al., 2006; Chalbot et al., 2014, 2016;Lopes et al., 2015). These sharp signals included low molecular weight formate ( 8.44 ppm), terephthalic acid ( 8.01 and 8.12 ppm), phthalic acid ( 7.457.47 and 7.58 ppm), glucose ( 3.883.91 and 3.813.85 ppm), fructose ( 3.793.84 ppm), trimethylamine ( 2.71 and 2.89 ppm), dimethylamine ( 2.72 ppm), and monomethylamine ( 2.55 ppm). It

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Figure 4. 1H NMR spectra of HULIS in smoke PM2.5 from combustion of rice straw (a), corn straw (b), pine branch (c), and coal (d), and in ambient PM2.5 (e). The segments from 3.30 to 3.35 and 4.80 to 5.40 ppm were removed from all NMR spectra due to MeOH and H2O residues. The peaks were assigned to specic compounds as follows: formate (Fo), terephthalic acid (TA), phthalic acid (PA), glucose (G), fructose (F), trimethylamine (TMA), dimethylamine (DMA), and monomethylamine (MMA).

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Table 6. The proton species and corresponding content percentage of HULIS in smoke PM2.5 from combustion of rice straw, corn straw, pine branch, and coal, and in ambient PM2.5.

Sources Types/sites Isolation methods HC a HCC = HCO ArH References

(0.62.0 ppm) (2.03.2 ppm) (3.44.4 ppm) (6.58.5 ppm)

Rice straw Burning emissions HLB 34b 30 10 27 Present work Corn straw Burning emissions HLB 31 26 19 24Pine branch Burning emissions HLB 45 22 14 19Coal Combustion emissions HLB 27 40 2 31PM2.5 Urban aerosol HLB 51 31 11 6

Rainwater Terrestrial/marine C18 51.4 32.1 15.0 1.4 Miller et al. (2009) inuenced (0.51.9) (1.93.3) (3.44.5) (6.59.0)

Rainwater Urban DAX-8 4551 2229 1724 27 Santos et al. (2012)(0.61.8) (1.83.2) (3.24.1) (6.58.5)

TSP Urban aerosol HLB 53.959.8 20.126.6 10.115.8 3.79.4 Song et al. (2010)(0.72.0) (2.03.2) (3.34.5) (6.58.3)

PM2.5 Urban aerosol ENVI-18, HLB, 3747 3337 1318 5.812 Fan et al. (2014)

XAD-8 and DEAE (0.61.9) (1.93.2) (3.44.4) (6.58.5)

PM2.5 Urban aerosol DAX-8 43.757.5 28.334.7 7.315.1 0.69.1 Lopes et al. (2015)

(0.51.9) (1.93.2) (3.34.1) (6.58.3)

a Investigation on the basis of the chemical shift assignments (unit: ppm). b Relative abundance of each type of protons.

is worth noting that all BB-derived HULIS present more sharp glucose and fructose resonances than atmospheric HULIS in 1H NMR spectra, but they were absent for coal-combustion-derived HULIS. On the other hand, coal-combustion-derived HULIS contain more sharp resonances of terephthalic acid and phthalic acid than atmospheric HULIS, but they were absent for BB-derived HULIS. Moreover, both BB and coal-combustion-derived HULIS exhibit many sharp signals between 6.5 and 8.5 ppm, which could be ascribed to aromatic structures, such as substituted phenols and alkylbenzenes (around 6.67.0 ppm), benzoic acids, esters, and nitroaromatics (Suzuki et al., 2001; Chalbot et al., 2014).

Although some sharp peaks were identied above, most of the signals in the spectra of all HULIS fractions appeared as a continuous unresolved distribution. This suggests that HULIS consist of a complex mixture of organic substances (Samburova et al., 2007; Song et al., 2012; Fan et al., 2013; Lopes et al., 2015). The integrated 1H NMR signal over specic ranges of chemical shift has been used previously to quantify the contribution of organic functional groups in HULIS from urban/rural aerosols (Song et al., 2012; Fan et al., 2013; Lopes et al., 2015) and rainwater (Miller et al., 2009; Santos et al., 2009, 2012). Accordingly, four main regions of chemical shifts were assigned and integrated in the spectra: H = 0.62.0 ppm (aliphatic protons in alkyl chains,

[HC]); H = 2.03.2 ppm (aliphatic protons attached to C

atoms adjacent to a carbonyl or aromatic group [HCC =]);

H = 3.44.4 ppm (protons on C atoms singly bound to O

or other heteroatoms, indicative of protons associated with carbohydrates, ethers, or esters, [HCO]); and H = 6.5

8.5 ppm (aromatic protons, [ArH]). It is worth noting that a few distinct weak peaks between 9 and 10 ppm were ob-

served in the primary HULIS in fresh soot particles, and can be attributed to aldehydic protons, [HC = O] (Ziemba

et al., 2011). However, they were absent in the atmospheric HULIS or WSOM in this study and in other studies (Dece-sari et al., 2005, 2007; Cavalli et al., 2006; Samburova et al., 2007; Song et al., 2012; Fan et al., 2013; Lopes et al., 2015).This region only accounts for a minor fraction (< 2 %), and therefore was not considered further.

Table 6 shows the distribution of the four types of protons described above, estimated from the area of the observed 1H

NMR regions for different HULIS samples. The four types of primary HULIS in fresh smoke particles contained a relatively high content of HC (27 %45 %), HCC = (22 %

40 %), and ArH (19 %31 %) groups, and a relatively low content of the HCO group (2-19 %). These four functional groups have also been observed in the 1H NMR spectra of atmospheric HULIS in this study and in other studies, but the relative distribution of these four functional groups are different. The atmospheric HULIS in ambient aerosols from this work and other studies (Song et al., 2012; Fan et al., 2013;Lopes et al., 2015) and in rainwater (Miller et al., 2009; Santos et al., 2009, 2012) were all characterized by the highest content of [HC] (3760 %), moderate content of [HCC =] (2037 %) and [HCO] (1024 %), and the lowest

content of [ArH] (112 %). It was noted that the relative content of [ArH] groups (1931 %) in primary HULIS was signicantly higher than that in atmospheric HULIS. This suggests that primary HULIS contained more aromatic structures, which is consistent with the elemental composition, UVvis spectra, EEM uorescence spectra, and FTIR spectra results. This result is also consistent with the observations of more aromatic protons in HULIS in colder seasons ascribed to BB inuence (Song et al., 2012; Lopes et al., 2015).

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X. Fan et al.: Comprehensive characterization of humic-like substances 13335

Although similarities existed, some differences in functional groups distributions were also observed between the primary HULIS from BB and coal combustion. As shown in Table 6, there was a relatively higher content of [HCC =]

(40 %) and [ArH] (31 %) in primary HULIS from coal combustion than from BB, indicating that the primary HULIS in coal smoke contained more unsaturated aliphatic (i.e., carbonyl groups (C = O)) and aromatic structural groups. In ad

dition, the content of [HCO] in HULIS from coal combustion was only 2 %, which was signicantly lower than in HULIS from BB. As described above, the [HCO] group was assigned to protons associated with carbohydrates and ethers. Therefore, these differences could be ascribed to the fact that the HULIS from BB contained a relatively high content of carbohydrate-derived compounds. The lower molar O / C and mass OM / OC ratios, and lower intensity of peaks at 1516 and 1045 cm1 and higher intensity of peaks at 1637, 1610, 1458, and 1385 cm1 in the FTIR spectra of HULIS from coal burning, all support this nding. For the HULIS from BB, a relatively high content of [HC] and low content of [ArH] were observed for HULIS from pine branch combustion when compared to the HULIS from rice straw and corn straw combustion. These results suggest that the primary HULIS from pine branch combustion contained more aliphatic protons and fewer aromatic protons than the HULIS from rice straw and corn straw combustion.

3.7 Light absorption properties

Recently, the organic aerosols, not only black carbon or elemental carbon, have attracted more and more attention because of their light absorption effects. WSOM is an important fraction in organic aerosols; it has been documented to have strong light-absorbing properties (Chen and Bond, 2010; Hecobian et al., 2010; Cheng et al., 2011; Liu et al., 2013; Zhang et al., 2013; Du et al., 2014; Kirillova et al., 2014; Yan et al., 2015; Cheng et al., 2016; Kim et al., 2016;Park and Yu, 2016). The AAE and MAE365 have been used to reect the light-absorbing properties of water-soluble brown carbon (referred to as WSOM) in the above studies. However, the investigation on light-absorbing properties of primary HULIS from direct combustion emissions is very limited. As an important component of WSOM, the observation on light-absorbing properties of HULIS is valuable for further understanding on their environment effects.

Light absorption of primary HULIS in this study increased sharply towards shorter wavelengths (not shown), which is characteristic of brown carbon spectra (Du et al., 2014; Park and Yu, 2016). The AAEs of HULIS tted between wavelengths of 330 to 400 nm for rice straw, corn straw, pine branch, and coal combustion smoke PM2.5 were 8.2 0.6,

6.7 0.6, 6.7 0.7, and 13.6 0.2, respectively (Table 7).

The AAE values of primary HULIS from biomass burning are comparable to those of atmospheric HULIS from urban aerosols in this study (7.0 0.2) and from the Amazon

biomass burning aerosols in earlier research (6.46.8; Hoffer et al., 2006). Because of limited observations of AAEs of HULIS, the comparisons between HULIS and WSOM were conducted. As seen in Table 7, primary HULIS and WSOM from the same smoke PM2.5 almost present the same AAE values. Those AAE values of HULIS were also in the range of those of primary WSOM from BB (7.4-17.8) and atmospheric WSOM from urban/rural aerosols (5.38.3) reported in previous studies (Chen and Bond, 2010; Hecobian et al., 2010; Cheng et al., 2011, 2016; Liu et al., 2013; Zhang et al., 2013; Du et al., 2014; Kirillova et al., 2014; Yan et al., 2015; Kim et al., 2016; Park and Yu, 2016). It is worth noting that the AAE of HULIS from coal combustion is observed as13.6, which is signicantly higher than the AAEs of primary HULIS or WSOM from BB in this study and in Park and Yu (2016). The AAE is also substantially higher than that of atmospheric WSOM from ambient aerosols here and in previous studies (Hecobian et al., 2010; Cheng et al., 2011, 2016;Liu et al., 2013; Zhang et al., 2013; Du et al., 2014; Kirillova et al., 2014; Yan et al., 2015; Kim et al., 2016; Park and Yu, 2016).

The mass absorption efciency (MAE365), which characterizes the efciency of absorbing solar energy by per DOC of HULIS, was also investigated in this study.As observed in Table 7, the MAE365 values of primary

HULIS were 1.54 0.30, 2.09 0.41, 0.97 0.22, and

0.63 0.03 m2 gC1 for rice straw, corn straw, pine branch,

and coal smoke emissions, respectively. It is obvious that the MAE365 values of HULIS were higher than those of the corresponding WSOM, suggesting a stronger absorbing ability of HULIS. Moreover, these primary HULIS MAE365 values seem to be comparable to ambient WSOM MAE365 values(0.131.79 m2 gC1) in previous studies (Hecobian et al., 2010; Cheng et al., 2011, 2016; Liu et al., 2013; Zhang et al., 2013; Du et al., 2014; Kirillova et al., 2014; Yan et al., 2015; Kim et al., 2016; Park and Yu, 2016). For the four primary HULIS, it is noteworthy that MAE365 of primary

HULIS from BB was typically 1.53 times higher than

from coal combustion. It suggests that primary HULIS from BB contain more light-absorbing chromophores than HULIS from coal combustion, which could signicantly affect the light-absorbing abilities of organic aerosols.

4 Implications

As a signicant fraction of water-soluble organic matter, HULIS have been widely studied in recent years. However, the studies of primary HULIS directly emitted from combustion processes with respect to amount and chemical properties are still limited. This work is a comprehensive study for the primary HULIS from direct combustion of rice straw, corn straw, pine branch, coal, and diesel fuels. The results conrmed that combustion processes including BB and coal combustion are signicant sources of atmospheric HULIS,

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13336 X. Fan et al.: Comprehensive characterization of humic-like substances

Table 7. Summary of AAE and MAE365 of HULIS and WSOM (sometimes were inferred to water-soluble brown carbon (BrC)).

HULIS WSOM

Locations Sample type AAE MAE365 AAE MAE365 References(m2 g1) (m2 g1)

Laboratory Rice straw smoke PM2.5 8.2 0.6 1.54 0.30 8.1 0.8 1.24 0.33 Present work

Laboratory Corn straw smoke PM2.5 6.7 0.6 2.09 0.41 6.7 0.5 1.56 0.34

Laboratory Pine branch smoke PM2.5 6.7 0.7 0.97 0.22 7.0 0.7 0.79 0.22

Laboratory Coal smoke PM2.5 13.6 0.2 0.63 0.03 13.1 0.1 0.42 0.03

Guangzhou, China Urban PM2.5 7.0 0.2 0.93 0.06 6.7 0.1 0.80 0.03Laboratory Rice straw smoke PM2.5 8.3 0.6 (300400 nm) 1.37 0.23 Park and Yu (2016)

Laboratory Pine needles smoke PM2.5 7.4 1.1 (300400 nm) 0.86 0.09 Park and Yu (2016)

Laboratory Sesame stems smoke PM2.5 8.0 0.8 (300400 nm) 1.38 0.21 Park and Yu (2016)

Laboratory Wood smoke particles 8.617.8 (360500 nm) Chen et al. (2010)

Rondnia, Brazil BB background PM2.5 6.46.8 (300700 nm)1 Hoffer et al. (2006)

Southeastern USA Urban/rural PM2.5 6.28.3 (330500 nm) 0.410.87 Hecobian et al. (2010)

Beijing, China Urban PM2.5 7.5 0.9 (330480 nm) 1.79 0.24 Cheng et al. (2011)

Beijing, China Urban PM2.5 7.0 0.8 (330480 nm) 0.71 0.20 Cheng et al. (2011)

Los Angeles Basin Urban PM2.5 7.58 0.49 (300600 nm) 0.70-0.73 Zhang et al. (2013)

Atlanta, USA Urban/rural PM2.5 0.130.53 Liu et al. (2013) Beijing, China Urban PM2.5 0.511.26 Du et al. (2014) Gosan, Korea Rural PM2.5 and TSP2 5.67.7 (330400 nm) 0.31.1 Kirillova et al. (2014)

Beijing, China Urban PM2.5 5.83 0.51 (330400 nm) 0.73 0.15 Yan et al. (2015)

Beijing, China Urban PM2.5 5.30 0.44 (330400 nm) 1.54 0.16 Yan et al. (2015)

Beijing, China Urban PM2.5 7.28 0.24 (310450 nm) 1.22 0.11 Cheng et al. (2016)

Seoul, Korea Urban PM2.5 5.849.17 (300700 nm) 0.281.18 Kim et al. (2016)

1 Representing the range of wavelength chosen for tting. 2 total suspended particulate.

but the vehicular exhaust source for primary HULIS may be negligible. It is noted that this is the rst time that coal combustion was identied as an important source of primary HULIS. Moreover, the chemical properties and structures of primary HULIS from combustion processes were really comprehensively characterized. Many similarities of chemical aspects were observed between primary HULIS and atmospheric HULIS, but some distinct features were also identied for the primary HULIS. These comprehensive characterizations of primary HULIS in smoke PM2.5 are very helpful for the better understanding of the chemical nature of primary HULIS from direct combustion emissions and their contribution to atmospheric HULIS. Nevertheless, some questions still remain, and more efforts should be made in the future to investigate the following: (1) the emission factors and chemical characteristics of primary HULIS formed from combustion of more types of biomass materials, coals, etc.; (2) the emission factors and chemical characteristics of primary HULIS formed under controlled combustion conditions (e.g., aming or smoldering burns, combustion temperature, and air dilution ratio); and (3) the aging process of primary HULIS in the atmospheric environment.

5 Conclusions

In this work, the primary HULIS fractions in smoke PM2.5 emitted from the combustion of biomass materials and fossil fuels were isolated and comprehensively characterized by various analytical methods, including TOC analysis, elemen-

tal analysis, UVvis, EEM uorescence, FTIR, and 1H NMR

spectroscopy. The main conclusions were as follows.

1. The HULIS fractions were important components of smoke PM2.5 obtained from the combustion of biomass materials and coal, and accounted for 5.323.4 of PM,5.221.7 of TC, and 45.566.1 of WSOC, respectively.

These results indicate that BB and coal combustion are all important sources of HULIS in atmospheric aerosols. However, the HULIS fractions in diesel soot only accounted for 0.8 % of soot particles, suggesting that the primary vehicular exhaust source for atmospheric HULIS may be negligible.

2. The primary and atmospheric HULIS were very similar in many aspects. At rst, they had similar chemical compositions, in which C and O were the dominant elements. Moreover, many similarities in chemical properties and structures were also detected. For example, the UVvis spectra of primary HULIS and atmospheric HULIS were all characterized by features that indicated that the absorbance decreased as the wavelength increased. The two main peaks assigned to fulvic-like (peak A) and protein-like (peak B) uorophores were both observed in the EEM spectra of primary and atmospheric HULIS. In the case of the 1H NMR analysis, four main regions of chemical shifts, assigned to [HC], [HCC =], [HCO], and [ArH] in the primary

HULIS, were also found in atmospheric HULIS. The AAE and MAE365 of the BB-derived primary HULIS

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X. Fan et al.: Comprehensive characterization of humic-like substances 13337

were similar to those of atmospheric HULIS and/or WSOM.

3. There were also some differences identied between primary and atmospheric HULIS. At rst, the O / C atomic ratios of coal-combustion-derived HULIS were signicantly lower than the ratio for atmospheric HULIS samples. Moreover, the primary HULIS contained more polycyclic aromatic and conjugated compounds than atmospheric HULIS, as consistently revealed by the UVvis, EEM uorescence, FTIR, and

1H NMR spectroscopy analysis. For example, primary HULIS exhibit relative higher absorbance in shorter wavelength regions than atmospheric HULIS in the UVvis spectra. The relative content of the [ArH] group in primary HULIS was signicantly higher than in atmospheric HULIS, as shown by the 1H NMR analysis. In addition, many sharp signals of organic species ascribed to low molecular weight aromatic organic compounds were observed in the 1H NMR spectra of primary HULIS, but they were not as abundant in the 1H

NMR spectra of atmospheric HULIS.

4. Some distinct features were also identied among the four types of primary HULIS. For example, the BB HULIS contain a relatively higher content of O-containing components than HULIS from coal combustion as revealed by elemental analysis. In addition, the results from the FTIR and 1H NMR spectroscopy indicated that the primary HULIS from BB contained relatively high contents of lignin-like and carbohydrate-derived structures, while the primary HULIS from coal combustion contained relatively high levels of aromatic structures. The MAE365 values of BB HULIS are 0.97

2.09 m2 g1, which are higher than that of coal combustion HULIS, suggesting that the former has stronger light absorption properties. For the three types of BB HULIS, a relatively higher content of [HC] and lower content of [ArH] were observed for HULIS in pine branch smoke than HULIS in the rice straw and corn straw smokes, suggesting that the primary HULIS from pine combustion contained more aliphatic protons and less aromatic protons.

6 Data availability

Data used in this paper can be provided upon request by e-mail to the corresponding authors.

Acknowledgements. The work was supported by the Natural Science Foundation of China (grants 41390242, 41473104, and 41173110), and the Foundation for Leading Talents from the Guangdong province government. The authors want to thank Shuiping Wu from Xiamen University for offering the possibility to prepare and collect smoke PM2.5 samples in their own resuspension

chamber in the State Key Laboratory of Marine Environmental Science.

Edited by: J. RobertsReviewed by: A. C. Duarte and one anonymous referee

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