Abstract
This study is aim to illustrate Phyllostachys edulis’ role in affecting air quality under hazy day and solar day. P. edulis is a crucial plants growing well at suburban area at China Southern. In this manuscript, on 2 weather conditions (hazy day; solar day), changes in atmospheric particulate matter (PM), polycyclic aromatic hydrocarbons (PAHs), associated volatile organic compounds (VOCs), and PAHs in leaves and soils were measured, with PM-detection equipment and the GC-MC method, in a typical bamboo forest at suburban areas. The results showed that: (1) Bamboo forest decreased atmospheric PM2.5 and PM10 concentrations significantly by 20% and 15%, respectively, on the hazy day nightfall time, when they were times higher than that on any other time. Also, similar effects on atmospheric PAHs and VOCs were found. (2) Significant increases in PAHs of leaves and soil were found inside the forest on the hazy day. (3) Bamboo forest also reduced the atmospheric VOC concentrations, and changed the compounds of 10 VOCs present in the highest concentration list. Thus, bamboo forests strongly regulate atmospheric PM2.5 through capture or retention, for the changes in atmospheric VOCs and increase in PAHs of leaves and soil.
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Introduction
With the development of the economy, people demand a better living quality. However, the air quality decreases and hazy weather occurs frequently to affect human. The hazy day affected more than 17 provinces with1.43 million km2 and over 0.6 billion people at 2013 in China1. Particulate matter (PM), especially fine particulates with an aerodynamic diameter less than 2.5 mm (PM2.5) and 10 mm (PM10), is very important indicator for hazy day. With the high pollution air continuously diffused in China at the beginning of 2013, 5 strong haze pollutions occurred in Beijing-Tianjin-Hebei region. At the most serious time, PM2.5 broke through 600 μg/m3, PM1 broke through 300 μg/m3, and the concentration of organic matter, sulfate and nitrate in PM1 reached 160,70,40 μ/m3 2. PM2.5 and PM10 can adversely affect human health, resulting in premature mortality, pulmonary inflammation and accelerated atherosclerosis, among other conditions3,4. PM2.5 can easily pass through the nose and mouth, then penetrate the lungs, and subsequently cause a range of effects on humans, such as impaired lung function and the loss of hemoglobin oxygen ability, eventually leading to respiratory and cardiovascular diseases5,6,7.
In recent years, many studies indicated that trees can significantly reduce PM2.5 and can absorb gaseous air contaminants8,9,10,11, especially at urban and suburban areas. Studies indicated that approximately 215000 t of total air PM10 were removed by urban trees in the United States12, and an increase in tree cover from 3.7% to 16.5% removed approximately 200 tons of PM10 each year in the West Midlands13. Forest canopies significantly altered the sulfur concentration and sedimentation rate of PM2.5 in a coniferous forest in central Japan and in a Norway spruce forest14,15. The ability of trees to clean the air might be related to the following: an increase in vegetation cover, which reduces the sources of PM2.5; PM can be absorbed by different tree organs; a decrease in wind speed may result in PM fallout; and changing wind direction might prevent PM2.5 transport into certain areas16,17,18,19. Various factors, e.g., the concentration of atmospheric PM2.5 and PM10, weather conditions, and tree biological characteristics, affect the ability of trees to remove PM2.516,20. Researchers have focused mainly on broad-leaved and coniferous trees, such as spruce, cypress, pine, gingko, and crepe myrtle21,22,23, whereas very few studies have been conducted on bamboo. In addition, research on the mechanisms of plant ecological responses to haze is insufficient.
PM is a complex mixture of elemental carbon, organic carbon, ammonium elements, and water24,25. The chemical properties of PM are responsible for observed health effects. Polycyclic aromatic hydrocarbons (PAHs) account for a large fraction of the mass of PM, and they might be important in PM toxicity26,27, e.g., BaP was identified as an indicator of carcinogenic risk28,29. PAHs can be present in water30,31, soils32, and plants33. The distribution of PAH was closely related to the meteorological conditions. When the fog and haze came up, the concentration tended to increase34. High levels of atmospheric PAHs impose serious environmental and biological problems28. Some studies aimed to illustrate the role that forests play in regulating atmospheric PAHs and PM2.5 and their relationship. Previous studies stated that plants might regulate PM2.5 and PAHs through the absorption of PAHs by plants or the forest ecology system33,35,36. Further research conformed that trees play an important role in accumulating contaminations37, and the PAH level in leaves is considered a biomonitor of air pollution38. However, limited research has been conducted to illustrate the relationship between bamboo and PAHs.
Volatile organic compounds (VOCs) are important precursor substances for photochemical smog39 and seriously threaten human health as important atmospheric pollutants40,41. VOCs can damage the human body through respiratory passages, the digestive canal and skin, increasing the probability of mutation, deformity and cancer. In addition, VOCs are important precursors of tropospheric ozone photochemical generation: ozone, the peroxide group (PAN) and other photochemical oxidants are produced by reactions between VOCs and NOx, which simultaneously generate a range of free radicals, aldehydes, acids, and ketones, among other substances42. Changes in VOCs are strongly related to PM43,44 because photooxidation products of biogenic VOCs, mainly isoprene and monoterpenes, are significant sources of atmospheric PM in forested regions42,45,46. Thus, the role of VOCs in forest-regulated PM2.5 is an important research field.
Phyllostachys edulis is an important tree species with a high economic and ecologic value. The land area covered by P. edulis exceeds 4.43 million hm2 in China. And, many people focused on the developing of forest travel at lots of forest cities, such as Huzhou, Quzhou, Lishui, et al. at Zhejiang Province. These forest cities had one similar ecology factor that many forest land were grow at the suburban area. And P. edulis is one mainly plants that grow well at suburban area. Many previous researchers noted that that forest ecosystems have a significant effect on PM2.5 and PAHs12,47. However, few studies have focused on the relationship between bamboo forest and PM2.5, especially PAHs, an important component of PM2.5.
The aim of this study was to illustrate how P. edulis play a pivotal role in improving the air quality under solar and hazy day. Two types weather conditions were chosen to research the relationship between bamboo forest and air quality. The changes in atmospheric PM2.5, PAHs, and VOCs were observed in a typical bamboo forest. In addition, PAHs in bamboo leaves and soil were also measured to understand how pollutants enter into P. edulis forests. The following was hypothesized: (1) Bamboo forest can remove the atmospheric PM2.5 under hazy day; (2) Comparing on solar day, bamboo forest can absorb PAHs into leaves significantly on hazy day; and (3) On hazy day, components of atmospheric VOCs in bamboo forest changed.
Results
Changes in air quality on hazy and sunny days
Changes in atmospheric PM2.5 and PM10 concentration
The concentrations of PM2.5 and PM10 on the hazy day were significantly higher than those on the sunny day. On the hazy day, the concentrations of PM2.5 and PM10 ranged from 107.45–258.35 μg/m3 and 161.83–387.73 μg/m3, respectively, compared to those on the sunny day, which were stable at approximately to 8 μg/m3 and 40 μg/m3, respectively (Table 1). In addition, the ratio of PM2.5 to PM10 was significantly higher on the hazy day, i.e., over than 56% on hazy day, compared with 20% on the sunny day (Table 1).
The highest PM2.5 and PM10 were found at the nightfall time. The daily variations of PM2.5 and PM10 on the hazy day were greater than those on the sunny day and presented a trend of a slight increase followed by a sharp decrease and an increase to the highest concentrations at nightfall time, which reached 258.35 μg/m3 and 387.73 μg/m3, respectively, outside the forest (Table 1). By contrast, the PM2.5 and PM10 concentrations were lower than 170 μg/m3 and 275 μg/m3 at any other time, both inside and outside forest (Table 1).
The bamboo forest had a significant effect on the PM. The concentrations of PM2.5 and PM10 decreased significantly about 20% and 15%, respectively, inside the forest at nightfall time. In the morning and at night fall, the PM10 concentration in the interior of the forest was significantly lower than that outside the forest; no significant differences between the inside and outside of the forest were observed at any other time. At most times, the bamboo forest resulted in a decrease in the PM2.5 (Table 1). Thus, it can be inferred from this research that bamboo forests can buffer changes in PM2.5 and PM10 during the day time.
Changes in the atmospheric PAH content on hazy and sunny days
The total atmospheric content of the six main PAHs (Tair) on the hazy day was significantly higher than that on the sunny day. The main atmospheric PAHs were four-, five- and six-ring compounds (BahA, BaP, BbF, BkF, Icdp and BghiP), which are known to be principal components of PAHs. Tair exceeded 12 ng·m−3 on the hazy day, compared with 1.04 ng·m−3 on the sunny day (Table 2). In addition, the concentrations of the main PAHs, such as BbF, BkF, BaP, BahA, IcdP, and BghiP, were also higher than those on the sunny day (Table 2).
The bamboo forest had a similar effect on the atmospheric concentration of PAHs on the hazy and sunny days. On both days, Tair inside the forest was significantly lower than that outside the forest. On the sunny day, the lowest Tair measured inside the forest was 0.59 ng·m−3. On the hazy day, Tair inside the forest was 12.91 ng·m−3, compared with 14.44 ng·m−3 outside the forest (Table 2).
These results indicate that this bamboo forest had a positive effect in regulating atmospheric PAHs on the hazy day, resulting in improved air quality.
Changes in the atmospheric concentration of VOCs on hazy and sunny days
On the hazy day, the atmospheric VOC content was significantly higher than that on the sunny day, and the 10 VOC compounds present in the highest concentrations differed significantly between the hazy and the sunny day. The atmospheric VOC content inside and outside the forest reached 94.77 and 156.85 µg/m3 on the hazy day (Table 3), compared with only 62.53 and 76.40 µg/m3, respectively, on the sunny day (Table 4).
More than 9 compounds, such as benzoic acid, acetone, and decanal, which were present in the list of 10 highest concentrations inside or outside the forest on the hazy day were not the same as those for the sunny day (Tables 3 and 4). This might be caused by the haze and was correlated with the increase in PM2.5 in atmospheric.
The bamboo forest resulted in a decrease in the VOC content on both hazy and sunny days. On the hazy day, the concentration of VOCs inside the forest was 39.58% lower than that outside the forest, and half of the VOCs present in the highest concentrations differed between the inside and outside of the forest (Fig. 1). On the sunny day, the concentration of VOCs inside the forest was 18.15% lower than that outside the forest, and most of the compounds present in the highest concentrations were the same inside and outside the forest (Fig. 2). This indicated that the bamboo forest played a positive role in regulating atmospheric VOCs.
Total Ion Chromatogram of VOCs on hazy day. Part A, at the inside of P. edulis forest land; Part B, at the outside of P. edulis forest land; 1, Butane, 2-methyl-; 2, Propane, 2-methoxy-2-methyl-; 3, Acetic acid; 4, Toluene; 5, Benzene, 1,3-dimethyl-; 6, Benzaldehyde; 7, Acetophenone; 8, Nonanal; 9, Decanal; 10, Benzoic acid; 11, 1,3-Butadiene, 2-methyl-; 12, Acetone; 13, Pentane, 2-methyl-; 14, n-Hexane; 15, Carbon Tetrachloride. These VOCs were in the list of top 10 highest concentration compounds at the inside or outside of P. edulis forest land.
Total Ion Chromatogram of VOCs on sunny day. Part C, at the inside of P. edulis forest land; Part D, at the outside of P. edulis forest land; 1, Ethyl Acetate; 2, Benzene; 3, Propane, 1,2-dichloro-; 4, Toluene; 5, Acetic acid, butyl ester; 6, Formamide, N,N-dimethyl-; 7, Ethylbenzene; 8, Benzene, 1,3-dimethyl-; 9, o-Xylene; 10, Benzaldehyde; 11, Nonanal. These VOCs were in the list of top 10 highest concentration compounds at the inside or outside of P. edulis forest land.
Changes in the PAHs concentrations in leaves on hazy and sunny days
The total concentrations of the six main PAHs in leaves (Tleaf) were significantly higher on the hazy day. Tleaf inside the forest and at the forest edge was higher on the hazy than on the sunny day, by approximately 110% and 60%, respectively (Table 5). Further analysis indicated that the concentrations of most compounds (besides BkF and Bap) increased rapidly on the hazy compared with the sunny day.
On both the hazy and sunny days, Tleaf inside the forest was significantly higher than that at the edge of the forest and reached 182.35 and 86.99 μg/kg, respectively (Table 3). On the hazy day, Tleaf inside the forest was 130% higher than that at the edge of the forest. Most of the compounds exhibited similar trends.
It can be deduced that the bamboo forest had a positive effect in reducing atmospheric PAHs. On the hazy day, the increase in the PAH concentration of the leaves was correlated with the increase in outside forest atmospheric PAHs (Table 5), especially the leaves inside the bamboo forest; the PAH concentration decreased after a long time. In this study, the sunny day occurred later in the year than the hazy day, and the concentration of PAHs in leaves decreased, both inside and at the edge of the forest (Table 5). It can be inferred from this study that bamboo leaves can absorb some atmospheric PAHs, especially those inside in the forest. In addition, some of the PAHs absorbed by leaves may be transferred to other bamboo organs, water, or soil.
Changes in the concentrations of PAHs in soil on hazy and sunny days
On the hazy day, the total concentrations of the six main PAHs (Tsoil) in soil were significantly higher than those on the sunny day. Tsoil inside and at the edge of the forest on the hazy day was higher than that on the sunny day, by approximately 235% and 70%, respectively. In addition, the concentrations of all six compounds were higher on the hazy than on the sunny day (Table 6).
The bamboo forest also had an important effect on the PAH content of the soil on the hazy day. Specifically, the concentrations of all 6 PAH compounds in the soil inside the forest were higher than those at the edge of the forest on the hazy day; however, significant differences were only found for BkF, BaP and BghiP between the inside and edge of the forest.
Discussion
Although obvious bodily harm results from increasing PM2.5 concentrations, it is difficult to completely eliminate the production of PM2.5 from different sources in China due to the rapid rate of economic development of this country. Therefore, it is important that research is conducted on how to remove atmospheric PM2.5 and lower the concentrations of other atmospheric pollutants. Many studies have been conducted on the potential of trees as a mitigation tool for atmospheric particles. Forests have a significant positive effect on the environment through a reduction in pollution, or they directly affect PM in the atmosphere by removing particles13,48. Trees have been shown to significantly reduce atmospheric PM12,49, and an increase in tree vegetation can also help to remove PM13. In this study, the atmospheric PM concentrations were significantly decreased by the P. edulis forest. This might be related to the fact that P. edulis is an evergreen species that can reproduce and propagate through rhizomes. Previous studies showed that evergreen species had a greater ability to reduce PM than deciduous trees50, because the leaves of evergreen species persist year-round, especially in winter and spring when hazy fog occurs frequently, resulting in a greater reduction in PM17,51. In the present study, the PM10 concentration inside the forest was higher than that outside the forest at several times. This might be related to meteorological factors (e.g., temperature and humidity) in the early morning being different to those at other times, and this can affect the ability of trees to remove PM18. And trees may have a lower CO2 assimilation rate, which can also affect PM absorption in a forest51.
PAHs, a class of hydrocarbons that threaten human health, bind to PM2.534,52,53,54. As a large fraction of the mass of PM, are candidate components with respect to PM toxicity. In this study, the atmosphere contained a large amount of carcinogenic and mutagenic PAHs on the hazy day; BbF, BkF and BaP (5-ring compounds), followed by those with 4 and 6 rings, i.e., BahA, BghiP, IcdP, BbkF (BbF and BkF), were dominant in all TSP samples, which is consistent with reports for GuiYu54 and Hong Kong34. PAHs are removed by trees at the same time as PM2.5, and the decrease of PM2.5 might be a result of plant capture and retention into the bamboo forest leaves and soil. On the one hand, plant decreased PM2.5 concentration by capture PM in air. Previous documents showed that PM can be intercepted by plant organs, such as leaves, bark, and twigs, resulting in the removal of PM2.5. The intercepted particles can be absorbed into the tree, though most particles that are intercepted are retained on the plant surface. The ability to intercept PM2.5 varies with tree species48,55, roughness of leaves56,57, cilia number on leaves58,59, pore structure11, wax coat60, and environmental conditions16,49. Studies have indicated that PAHs are absorbed together with PM2.5 absorption33,56,61. This result is consistent with the findings of this study. In this study, atmospheric PAHs decreased and PAHs in bamboo leaves were significantly increased. The total concentrations of the six main PAHs in leaves (Tleaf) were significantly higher on the hazy day. On the other hand, retention by forests is an important way to reduce atmospheric PM2.5. Trees have the capacity to retain PM21,62. In this study, PAHs, an important component of PM2.5, accumulated significantly in soil on the hazy day. Researchers have reported that indicator matter in forest soils were significantly higher than in non-forest land15,63. Forests alter the sedimentation rate of PM2.5 and increase the rate at which PM infiltrates the soil. According to radioactive substances or the indicator substance tracking technique, PM in forests was significantly higher than that in non-forest land19,64. Studies conducted in coniferous forests of central Japan and in Norway spruce forests also indicated that the forest canopy significantly altered the sulfur concentration and sedimentation rate of PM2.514,19.
The effect of forest on air quality was more obvious under hazy weather condition. The effects of weather conditions on PM were very significant18,65,66.The wind speed affected the horizontal diffusion of aerosols. The temperature rise was conducive to aerosol diffusion and was also beneficial to secondary aerosol production. Humidity would cause ultra-fine aerosols to aggregate65. In the forest, the temperature increased, the vertical convection in the atmosphere increased, and the concentration of PM10 and PM2.5 in the forest belt would be reduced. The concentration of the relative humidity increased the concentrations of PM10 and PM2.566. Under the foggy conditions, the general temperature was lower and the wind speed was smaller. The droplets that make up the fog were suspended in the atmosphere near the ground layer. It was very easy to absorb the polluted particles in the air, which affected the distribution of organic pollutants in the atmosphere. The daily average concentration of PAHs monomer was significantly higher than that of sunny days, and maintained high concentration throughout the day and night34. When the air quality in foggy weather was particularly poor, it was easy to form haze. The level of PAHs in leaves was promoted under hazy day56. And there were many problems were found in plant materials being contaminated by PAHs67,68. For the exposure to pollution, such as PAH pollutants, the leaves’ surface and structure changed69, e.g PM was found in stomata70. And the leaves surface was more easily to bacterial and fungal infections. These changes caused high ability to retain water, and means that PAHs may affect the amount of retained rainfall indirectly37. Thus, the hazy day affected the plant materials, and plant leaves showed more ability to capture pollutants. These were in consisting to our study, that bamboo showed significant ability to remove PM2.5 and PAHs, and the PAHs in leaves increased significantly under hazy day.
VOCs are strongly related to PM2.5 because photochemical oxidation and ozonolysis of monoterpenes can lead to secondary organic aerosol (SOA) formation71,72. Photooxidation products of biogenic VOCs, mainly isoprene and monoterpenes, are significant sources of atmospheric PM in forested regions42. In this study, the concentrations of atmospheric VOCs were significantly different on the hazy and the sunny day, especially the 10 VOCs present in the highest concentrations. This might be because the air pollution had different sources of VOCs on the sunny and the hazy day. Changes in the sources of VOCs affect the components of VOCs39. This also indicated that the VOCs and PM2.5 were important factors contributing to the hazy day. Furthermore, atmospheric VOCs can be significantly regulated by plants40. The changes in atmospheric VOCs in this study might be attributed to changes in the weather condition or because the bamboo forest affects the components of VOCs. Vegetation releases numerous VOCs into the atmosphere, particularly isoprene, monoterpenes, and sesquiterpenes, as well as a series of oxygen containing compounds41. In addition, isoprene can also result in SOA, including species such as 2-methyltetrols (2-methylthreitol and 2-methylerythritol), C5-alkene triols (cis- and trans-2-methyl-1,3,4-trihydroxy-1-butene and 3-methyl-2,3,4-trihydroxy-1-butene) and 2-methylglyceric acid42,73. Isoprene SOA products have been detected at various forested sites around the world74,75, which is similar to this study because several substances were also observed in the bamboo forest. In addition, atmospheric VOC distribution might be affected by changes in the environment, as well as the plant canopy, which can change the wind speed, temperature, and humidity, among other factors76. This indicated that the bamboo forest regulated the VOCs to adapt to the polluted environment.
Materials and Methods
Experimental design
A P. edulis forest in Changxing, Zhe Jiang, was selected as the investigation object. Sampling was performed on a mountain in one of the countries of Changxing in the southeastern region of Zhejiang Province (30°43′–31°11′N, 119°33′–20°06′E). The climate of Changxing is classified as subtropical monsoon maritime, with an annual average temperature of 15.6 °C and annual precipitation of 1309 mm. The forest is a plantation land with a density about 180–210 plants/667 m2 and 12–15 m height. The land is far away from the nearest town about 7.2 km. And the 3–5 years old bamboo individuals were respect for about 70%.
The study consisted of 2 weather types (sunny day, hazy day) and 3 sites (interior of the bamboo forest, the edge of the bamboo forest, and outside the bamboo forest). There were 3 bamboo forest land were selected as 3 replications. Atmospheric PM2.5, PM10, PAH and VOC concentrations were measured at 3 sites. The PAH concentrations in both bamboo leaves and soil were analyzed at 2 sites (interior and the outside of the bamboo forest). The hazy day treatment was selected at a time when the haze had persisted for more than one month and the PM2.5 concentration exceeded 200 µg•m−3. The sunny day was selected at a time when the weather was continuously fine for more than one week. The hazy day was considered as air pollution treatment, and the sunny day was considered as control treatment. This work is guided on “Observation Methodology for Long-term Forest Ecosystem Research of National Standards of the People's Republic of China (GB/T 33027-2016).
Sampling method
Method used for air sample collection
The method for air sample collection was based on the industrial or national standard that focused on the monitoring of air or particulate quantity77,78. Medium-flow air samplers (Wuhan Tianhong Instrument Limited Liability Company, Wuhan, China) were used to collect samples with a flow rate of 100 L/min for PAH analysis and a flow rate of 0.5 L/min for VOC analysis. The ambient air samples were collected from the atmosphere at heights of approximately 1.5 m above ground.
Before sampling, filters were conditioned at 25 °C and 40% relative humidity in a desiccator for at least 24 h. PAH-associated contaminants were isolated from the atmosphere by drawing air through a Whatman quartz fiber filter (QFF, 800–1000). VOC-associated contaminants were isolated from the atmosphere by drawing air through a Whatman quartz fiber filter for approximately 30 min. Background contamination was monitored by using operational blanks, which were processed simultaneously with the samples. After sampling, the filters were wrapped in aluminum foil and stored in ziplock bags at −20 °C.
Methods for leaf and soil sample collection
Soil and leaf samples were collected according national or industrial standards that are used to monitor the environment79,80. At every forest land, the bamboo leaves were selected on the branches at about 3 m height in 4 directions, and 10 leaves were collected every direction. These were done 3 replications and samples gather into an ice bag. Then the samples were taken to the laboratory to processing.
The surface soil samples (0–20 cm) were collected with quartering division method at every bamboo land. 3 replicate samples collected from one land were mixed uniformly, respectively. The soil samples were ground with a pestle and mortar, screened through an 80-mesh sieve, and stored in a mason jar for the determination of PAHs and VOCs.
Methods for detection and analysis
Method for PM2.5 and PM10 concentration detection
PM2.5 and PM10 concentrations were detected using a dust detector (DUSMATE) according to the industrial standard77,81. The instrument was adjusted to the on-line monitoring system before detection. PM2.5 and PM10 concentrations were detected every 3 h at a height of 1.5 m during the monitoring period.
Extraction and analysis of PAHs
PAH analysis was performed using the GC-MC method, and the analysis details were provided by the relative industrial standard for the quantification of air and particulate material77 and elsewhere54. Briefly, the filter samples from ambient air, soil and bamboo leaves were repeatedly reflux extracted using a soxhlet extractor with aether:hexane (1:9) for at least 16 h, no less than 4 times per hour. Anhydrous sodium sulfate (15 g) was added to the extract to ensure free flow of sodium sulfate particles. The extracts were then concentrated to 5.0 ml using rotary evaporation. Subsequently, hexane (5–10 ml) was added and rotary evaporated until less than 1 ml hexane remained. To prevent interference, extracts were purified using silica gel chromatography. Extracts were analyzed for PAHs by gas chromatography mass spectrometry using Agilent’s New 7890B Gas Chromatograph and a 5977 A Series Mass Selective Detector (GC-MSD) operated in the full ion scanning mode.
Analysis of VOCs
VOCs were analyzed using the industrial standard methods for air and particulate monitoring77,78. The VOC concentration was measured using a thermal desorbed instrument (Tekmar 6000/6016) interfaced with a gas chromatograph (HP 7890 B) and mass selective detector (HP 5977 A, AMA Co., Germany). The working conditions of the TDS were as follows: gas pressure of 20 kPa, inlet temperature of 250 °C desorption temperature of 250 °C for 10 min; cold trap temperature held at 120 C for 3 min, followed by a rapid increase to 260 °C. An HP-5MS column (50 m, i.d. 0.25 mm, and film thickness 0.25 m) was used for chromatographic separation. The temperature program was 40 °C for 3 min followed by 10 °C/min up to 250 °C for 3 min and then an increase to 270 °C. The ion energy of the MS (type 5975 C, Agilent) was 70 eV; the ion source temperature was 230 °C; the Quadrupole temperature and the interface temperature were 150 and 280 °C, respectively; and the mass spectrometry scanning mass ranged from 28 to 450 m/z. The retrieval and qualitative analysis of the mass spectrometry data were accomplished using the NIST 2008 library, which was housed in the computer of the temperature instrument. In addition, the chromatographic peak area normalization method was used for the calculation of the relative concentrations of the mass spectrometry data.
Statistical Analysis
Analysis of variance and Duncan’s new multiple range tests were performed with SAS 9.2 Institute Inc.™ (1999) software. The data are presented as means ± S.D. Differences at P < 0.05 were considered significant.
Availability of materials and data
The datasets generated during and analyzed during the current study are available from the corresponding author on reasonable request.
Conclusion
Bamboo forest shows strong effects on reduction of the air pollution. The concentrations of atmospheric PM2.5, PM10, PAHs and VOCs decreased at inside of forest land. And by tracing the increase of PAHs in bamboo leaves and soils, the PM2.5 might be cleaned by plant capture and bamboo forest renitent. These can illustrate that bamboo forest remove PM2.5 by gathering PAHs into the forest ecosystem factors, e.g. bamboo leaves and soils. And bamboo forest also changed the VOCs concentration in air, and also changed the types of 10 VOCs present in the highest concentration list inside and outside forest land, to affect PM2.5. PAHs were important substances to explain the PM2.5 regulate way. These findings illustrated a regulating way for P. edulis under haze day, and were help to understand its ecology value, especially the role of bamboo forest played in providing ecosystem services at urban or suburban. These also indicated that it is essential to start the research on the effect of P. edulis forest under different plantation types, different areas, and evenly the effect of other bamboo species. Also, these findings demonstrated that it was also essential to research the responses of bamboo to ecological factors, especially the polluted air, to understand the biological and physiological mechanism. And many physiological ecology study methods, such as isotopic tracing, confocal laser scanning microscope, manual simulation, et al., might help to do it well.
References
Zhang, Q. L. The Ministry of Environmental Protection reported on the air quality of some cities on January 30th. China Environmental News, January 30, 01 edition (2013).
Qiu, C. H. The special study of the Chinese Academy of Sciences restores the weather generation process of the Beijing-Tianjin-Hebei ash. China Youth Daily, February 16, 03 edition (2013).
Pope, C. et al. Lung cancer, cardiopulmonary mortality, and long-term exposure to fine particulate air pollution. Jama-J. Med. Assoc. 287, 1132–1141 (2002).
Kanakidou, M. et al. Organic aerosol and global climate modelling: a review. Atmos. Chem. Phys. Disc. 4, 1053–1123 (2004).
Samet, J. et al. Fine particulate air pollution and mortality in 20 US cities, 1987–1994. New Engl. J. Med. 343, 1742–1749 (2000).
Peters, A. et al. Increased particulate air pollution and the triggering of myocardial infarction. J. Am. Heart. Assoc. 103, 2810–2815 (2001).
Pope, C. et al. Particulate air pollution as a predictor of mortality in a prospective study of US adults. Am. J. Resp. Crit. Care Med. 151, 669–674 (1995).
Nowak, D. J. Air pollution removal by Chicago’s urban forest. In Chicago’s Urban Forest Ecosystem: Results of the Chicago Urban Forest Climate Project, McPherson, E., Nowak, D., Rowntree, R., Eds., U.S. Department of Agriculture, Forest Service, Northeastern Forest Experiment Station: Radnor, PA, USA; pp. 63–82 (1994).
Akbari, H., Pomerantz, M. & Taha, H. Cool surfaces and shade trees to reduce energy use and improve air quality in urban areas. Sol. Energy 70, 295–310 (2001).
Bass, B. & Baskaran, B. Evaluating rooftop and vertical gardens as an adaptation strategy for urban areas. National Research Council Canada Technical Report NRCC, 46737 (2001).
Hofman, J. et al. On the relation between tree crown morphology and particulate matter deposition on urban tree leaves: A ground-based LiDAR approach. Atmos. Eniviron. 99, 130–139 (2014).
Nowak, D., Crane, D. & Stevens, J. Air pollution removal by urban trees and shrubs in the United States. Urban For. Urban Green. 4, 115–123 (2006).
McDonald, A. et al. Quantifying the effect of urban tree planting on concentrations and depositions of PM10 in two UK conurbations. Atmos. Eniviron. 41, 8455–8467 (2007).
Horváth, L. Dry deposition velocity of PM2.5 ammonium sulfate particles to a Norway spruce forest on the basis of S-and N-balance estimations. Atmos. Eniviron. 37, 4419–4424 (2003).
Matsuda, K. et al. Deposition velocity of PM2.5 sulfate in the summer above adeciduous forest in central Japan. Atmos. Eniviron. 44, 4582–4587 (2010).
Beckett, K., Freer, S. & Taylor, G. Effective tree species for local air-quality management. J. Arboriculture 26, 12–19 (2000).
Nowak, D. & Dwyer, J. Understanding the benefits and costs of urban forest ecosystems. In Urban and community forestry in the Northeast; Kuser J. E., Eds.; Springer science and business media: New York, USA; pp. 25–46 (2007).
Tallis, M. et al. Estimating the removal of atmospheric particulate pollution by the urban tree canopy of London, under current and future environments. Landscape Urban Plan. 103, 129–138 (2011).
Liu, J. et al. Dry deposition of particulate matter at an urban forest, wetland and lake surface in Beijing. Atmos. Eniviron. 125, 178–187 (2016).
Liu, J. et al. Particle removal by vegetation: comparison in a forest and a wetland. Environ. Sci. Pollut. Res. Int. 24, 1597–1607 (2017).
Li, H. & Liu, X. Relation between leaf epidermal morphology and dust-retaining capability of main garden trees in Chengyang district of Qingdao city. Chin. J. Ecol. 27, 1659–1662 (2008).
Guo, X., Zhang, Q., Tang, L. & Hu, J. Study on the dust catching property of the several evergreen conifers in Huhhot. Chin. Agri. Sci. Bull. 25, 62–65 (2009).
Oishi, Y. Comparison of Pine needles and mosses as bio-indicators for polycyclic aromatic hydrocarbons. J. Environ. Prot. Ecol. 4, 106–113 (2013).
Hueglin, C. et al. Chemical characterization of PM2.5, PM10 and coarse particle at urban, near-city and rural sites in Switzerland. Atmos. Environ. 39, 637–651 (2005).
Cheng, M., Horng, C. & Lin, Y. Characteristics of atmospheric aerosol and acidic gases from urban and forest sites in central taiwan. B. Environ. Contam. Tox. 79, 674–677 (2007).
Panther, B., Hooper, M. & Tapper, N. A comparison of air particulate matter and associated polycyclic aromatic hydrocarbons in some tropical and temperate urban environments. Atmos. Eniviron. 33, 4087–4099 (1999).
Eiguren, F. & Miguel, A. Determination of semi volatile and particulate polycyclic aromatic hydrocarbons in SRM 1649a and PM2.5 samples by HPLC-fluorescence. Polycycl. Aromat. Comp. 23, 193–205 (2003).
World Health Organization. WHO air quality guidelines for particulate matter, ozone, nitrogen dioxide and sulfur dioxide (Global update 2005, summary of risk assessment)[EB/OL].[2012-06-06]. http:whqlibdoc.who.int/hq/2006/WHO_SDE_PHE_OEH_06.02_eng.pdf (2005).
IARC (International Agency for Research on Cancer). Some non-heterocyclic polycyclic aromatic hydrocarbons and some related Exposures. IARC Monogr. Eval. Carcinog. Risk Hum. 92 (IARC, Lyon) (2010).
Manoli, E. et al. Polycyclic aromatic hydrocarbons in the bulk precipitation and surface waters of Northern Greece. Chemosphere 41, 1845–1855 (2000).
Wang, Z. et al. Distribution and sources of polycyclic aromatic hydrocarbons from urban to rural soils: a case study in Dalian, China. Chemosphere 68, 965–971 (2007).
Patrolecco, L. et al. Occurrence of priority hazardous PAHs in water, suspended particulate matter, sediment and common eels (Anguilla anguilla) in the urban stretch of the River Tiber (Italy). Chemosphere 81, 1386–1392 (2010).
Pan, Y. J., Tian, D., Tang, D. & Kang, W. X. Concentrations and spatial distribution of polycyclic aromatic hydrocarbons (PAHs) in a Cinnamomum camphora stand. Scientia Silvae Sinicae 40, 2–7 (2004).
Gu, K. et al. Characteristics of polycyclic aromatic hydrocarbons (PAHs) in particles and the influence of foggy weather. China Environ. Sci. 31, 1233–1240 (2011).
Terzaghi, E. et al. Towards more ecologically realistic scenarios of plant uptake modelling for chemicals: PAHs in a small forest. Sci. Total Environ. 505, 329–337 (2015).
Alagić, S., Maluckov, B. & Radojičić, V. How can plants manage polycyclic aromatic hydrocarbons? May these effects represent a useful tool for an effective soil remediation? A review. Clean Technol. Environ. Policy 17, 597–614 (2015).
Klamerus-Iwan, A. et al. Seasonal variability of leaf water capacity and wettability under the influence of pollution in different city zones. Atmos. Poll. Res. 9, 455–463 (2018).
Alfani, A. et al. Leaves of Quercus ilex L. as biomonitors of PAHs in the air of Naples (Italy). Atmos. Environ. 35, 3553–3559 (2001).
Liu, C. et al. Analysis of volatile organic compounds concentrations and variation trends in the air of Changchun, the northeast of China. Atmos. Eniviron. 34, 4459–4466 (2000).
Jackson, R. et al. Belowground consequences of vegetation change and their treatment in models. Ecol. Appl. 10, 470–483 (2000).
Sharkey, T. & Yeh, S. Isoprene emission from plants. Annu. Rev. Plant Mol. Biol. 52, 407–436 (2001).
Claeys, M. et al. Formation of secondary organic aerosols through photooxidation of isoprene. Science 303, 1173–1176 (2004).
Edney, E. et al. Formation of 2-methyltetrols and 2-methylglyceric acid in secondary organic aerosol from laboratory irradiated isoprene/NO/SO2/air mixtures and their detection in ambient PM2.5 samples collected in the eastern United States. Atmos. Eniviron. 39, 5281–5289 (2005).
Zou, Y. et al. An analysis of the impacts of VOCs and NOx on the ozone formation in Guangzhou. Atmos. Chem. Phys. Discuss. 14, 18849–18877 (2014).
Plewka, A. et al. Biogenic contribution to the chemical composition of airborne particles in a coniferous forest in Germany. Atmos. Environ. 40, s103–s105 (2006).
Liu, Y. et al. Characterization of atmospheric volatile organic compounds in Shenyang, China. Environ. Sci. 32, 2777–2785 (2011).
Tiwary, A. et al. An integrated tool to assess the role of new planting in PM10 capture and the human health benefits: A case study in London. Environ. Pollut. 157, 2645–2653 (2009).
Freer, S., Elkhatib, A. & Taylor, G. Capture of particulate pollution by trees: a comparison of species typical of semi-arid areas (Ficus nitida and Eucalyptus globulus) with European and North American species. Water Air Soil Pollut. 155, 173–187 (2004).
Bealey, W. et al. Estimating the reduction of urban PM10 concentrations by trees within an environmental information system for planners. J. Environ. Manage. 85, 44 (2007).
Ji, J. et al. Evaluation of absorbing haze PM2.5 fine particulate matters with plants in Beijing-Tianjin-Hebei region in China. Scientia Sin. Vit. 43, 694–699 (2013).
Nowak, D. et al. Modeled PM2.5 removal by trees in ten U.S. cities and associated health effects. Environ. Pollut. 178, 395–402 (2013).
Kiss, G. et al. Distribution of polycyclic aromatic hydrocarbons on atmospheric aerosol particles of different sizes. Atmos. Res. 46, 253–261 (1998).
Zheng, M. & Fang, M. Particle-associated polycyclic aromatic hydrocarbons in the atmosphere of Hong Kong. Water Air Soil Pollut. 117, 175–189 (2000).
Deng, W. et al. Atmospheric levels and cytotoxicity of PAHs and heavy metals in TSP and PM2.5 at an electronic waste recycling site in southeast China. Atmos. Environ. 40, 6945–6955 (2006).
Gupta, G., Kumar, B. & Kulshrestha, U. Impact and pollution indices of urban dust on selected plant species for green belt development: mitigation of the air pollution in NCR Delhi, India. Arab. J. Geosci. 9, 1–15 (2016).
Terzaghi, E. et al. Forest Filter Effect: Role of leaves in capturing/releasing air particulate matter and its associated PAHs. Atmos. Eniviron. 74, 378–384 (2013).
Zhang, T. et al. Particle-retaining characteristics of six tree species and their relations with micro-configurations of leaf epidermis. J. Beijing For. Univ. 39, 70–77 (2017).
Chai, Y., Zhu, N. & Han, H. Dust removal effect of urban tree species in Harbin. Chin. J. Appl. Ecol. 13, B1121–1126 (2002).
Yu, X. The characteristic of foliar dust of main afforestation tree species in Nanjing and association with leaf’s surface micro-structure. Nanjing Forestry University (2008).
Jouraeva, V. et al. Differences in accumulation of PAHs and metals on the leaves of Tiliaxeuchlora and Pyrus calleryana. Environ. Pollut. 120, 331 (2002).
Song, Y. et al. Behaviors of polycyclic aromatic hydroearbons (PAHs) and heavy metals in soil-plant system. Chin. J. Appl. Ecol. 6, 417–422 (1995).
Liu, L. et al. The dust retention capacities of urban vegetation-a case study of Guangzhou, South China. Environ. Sci. Pollut. R. Int. 20, 6601–6610 (2013).
Branford, D., Fowler, D. & Moghaddam, M. Study of aerosol deposition at a wind exposed forest edge using 210 Pb and 137 Cs soil inventories. Water Air Soil Poll. 157, 107–116 (2004).
Fowler, D. et al. Measuring aerosol and heavy metal deposition on urban woodland and grass using inventories of 210 Pb and Metal concentrations in soil. Water Air Soil Pollut. Focus 4, 483–499 (2004).
Lin, J. et al. Relationship between meteorological conditions and particle size distribution of atmospheric aerosols. J Meteor. Environ. 25, 1–5 (2009).
Liu, X. H. et al. Pollution characteristics of atmospheric particulates in forest belts and their relationship with meteorological conditions. Chin. J. Ecol. 33, 1715–1721 (2014).
Sadowska-Rociek, A., Cieślik, E. & Sieja, K. Simultaneous sample preparation method for determination of 3-monochloropropane-1, 2-diol and polycyclic aromatic hydrocarbons in different foodstuffs. Food Analytical Methods. 9, 2906–2916 (2016).
Yang, B. et al. PAHs uptake and translocation in Cinnamomum camphora leaves from Shanghai, China. Sci. Total Environ. 574, 358–368 (2017).
Srogi, K. Monitoring of environmental exposure to polycyclic aromatic hydrocarbons: a review. Environ. Chem. Lett. 5, 169–195 (2007).
Pérez-López, U. et al. Interacting effects of high light and elevated CO2 on the nutraceutical quality of two differently pigmented Lactuca sativa cultivars (Blonde of Paris Batavia and Oak Leaf). Sci. Hortic. 191, 38–48 (2015).
Hoffmann, T. et al. Formation of organic aerosols from the oxidation of biogenic hydrocarbons. J. Atmos. Chem. Phys. 5, 2947–2971 (1997).
Kavouras, I. & Stephanou, E. Direct evidence of atmospheric secondary organic aerosol formation in forest atmosphere through heteromolecular nucleation. Environ. Sci. Technol. 36, 5083–5091 (2002).
Wang, W. et al. Characterization of oxygenated derivatives of isoprene related to 2-methyltetrols in Amazonian aerosols using trimethylsilylation and gas chromatography/ion trap mass spectrometry. Rapid Commun. Mass Sp. 19, 1343–1351 (2005).
Clements, A. & Seinfeld, J. Detection and quantification of 2-methyltetrols in ambient aerosol in the southeastern United States. Atmos. Environ. 41, 1825–1830 (2007).
Kourtchev, I. et al. Determination of isoprene and α-/β-pinene oxidation products in boreal forest aerosols from Hyytiälä, Finland: diel variations and possible link with particle formation events. Plant Biol. 10, 138–149 (2008).
Wang, W. et al. Polar organic tracers in PM2.5 aerosols from forests in eastern China. Atmos. Chem. Phys. 8, 7507–7518 (2008).
Ministry of Environmental Protection of the People's Republic of China. HJ 646-2013. Ambient air and stationary source emissions-determination of gas and particle-phase polycyclic aromatic hydrocarbons with gas chromatography/mass spectrometry. Beijing:China Environmental Science Press, 2013.
Ministry of Environmental Protection of the People's Republic of China. HJ 644-2013. Ambient air- determination of volatile organic compounds-sorbent absorption and thermal desorption/gas chromatography mass spectrometry method. Beijing:China Environmental Science Press, 2013.
General administration of quality supervision, inspection and quarantine of the People's Republic of China, Ministry of Environmental Protection of the People’s Republic of China. GB 5085.3-2007. Identification standards for hazardous wastes- identification for extraction toxicity. Beijing:China Environmental Science Press, 2007.
Ministry of Environmental Protection of the People's Republic of China. HJ/T166-2004. The technical specification for soil environmental monitoring. Beijing:China Environmental Science Press, 2004.
General administration of quality supervision, inspection and quarantine of the People's Republic of China, Standardization administration of the People's Republic of China. GB/T 33027-2016. Methodology for field long-term forest ecosystem. Beijing:Standards Press of China, 2017.
Acknowledgements
The authors greatly appreciate the support of these foundations: 1. The Fundamental Research Funds for the Central Non-profit Research Institution of Chinese Academy of Forestry (CAF) (Grant No. CAFYBB2014QA039); 2. National Key R&D Program of China (2017YFC0505502). This work is also supported by CFERN & Beijing Techno solutions award funds on excellent academic achievements.
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Bi Y.F. had done the outdoor test tasks, analyzed the data and wrote the methods; Guo F.Y. wrote the part of the results, and contributed the Discussion; Yang L. analyzed the data of GC/MC data, and contributed to the Results and Discussion; Zhong H. and Wang Y.K. provided advice on manuscript proof, and contributed to the test method; Wu Z.Z. contributed to the design for this study; Wang A.K. had done part of the outdoor tasks; Du X.H. conceived and designed the experiments, and wrote the mainly body of the paper.
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Bi, Y.F., Guo, F.Y., Yang, L. et al. Phyllostachys edulis forest reduces atmospheric PM2.5 and PAHs on hazy days at suburban area. Sci Rep 8, 12591 (2018). https://doi.org/10.1038/s41598-018-30298-9
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DOI: https://doi.org/10.1038/s41598-018-30298-9
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