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Atmospheric Nitrogen Deposition at Two Sites in an Arid Environment of Central Asia

  • Kaihui Li,

    Affiliation Key Laboratory of Biogeography and Bioresource in Arid Land, Xinjiang Institute of Ecology and Geography, Chinese Academy of Sciences, Urumqi, China

  • Xuejun Liu ,

    likh@ms.xjb.ac.cn (CT); ecology2012@yahoo.cn (XL)

    Affiliation College of Resources and Environmental Sciences, China Agricultural University, Beijing, China

  • Wei Song,

    Affiliation Key Laboratory of Biogeography and Bioresource in Arid Land, Xinjiang Institute of Ecology and Geography, Chinese Academy of Sciences, Urumqi, China

  • Yunhua Chang,

    Affiliation Key Laboratory of Biogeography and Bioresource in Arid Land, Xinjiang Institute of Ecology and Geography, Chinese Academy of Sciences, Urumqi, China

  • Yukun Hu,

    Affiliation Key Laboratory of Biogeography and Bioresource in Arid Land, Xinjiang Institute of Ecology and Geography, Chinese Academy of Sciences, Urumqi, China

  • Changyan Tian

    likh@ms.xjb.ac.cn (CT); ecology2012@yahoo.cn (XL)

    Affiliation Key Laboratory of Biogeography and Bioresource in Arid Land, Xinjiang Institute of Ecology and Geography, Chinese Academy of Sciences, Urumqi, China

Correction

10 Jan 2014: Li K, Liu X, Song W, Chang Y, Hu Y, et al. (2014) Correction: Atmospheric Nitrogen Deposition at Two Sites in an Arid Environment of Central Asia. PLOS ONE 9(1): 10.1371/annotation/9f5d3b10-1021-4d7d-8bad-26e9b513176b. https://doi.org/10.1371/annotation/9f5d3b10-1021-4d7d-8bad-26e9b513176b View correction

Abstract

Arid areas play a significant role in the global nitrogen cycle. Dry and wet deposition of inorganic nitrogen (N) species were monitored at one urban (SDS) and one suburban (TFS) site at Urumqi in a semi-arid region of central Asia. Atmospheric concentrations of NH3, NO2, HNO3, particulate ammonium and nitrate (pNH4+ and pNO3) concentrations and NH4-N and NO3-N concentrations in precipitation showed large monthly variations and averaged 7.1, 26.6, 2.4, 6.6, 2.7 µg N m−3 and 1.3, 1.0 mg N L−1 at both SDS and TFS. Nitrogen dry deposition fluxes were 40.7 and 36.0 kg N ha−1 yr−1 while wet deposition of N fluxes were 6.0 and 8.8 kg N ha−1 yr−1 at SDS and TFS, respectively. Total N deposition averaged 45.8 kg N ha−1 yr−1at both sites. Our results indicate that N dry deposition has been a major part of total N deposition (83.8% on average) in an arid region of central Asia. Such high N deposition implies heavy environmental pollution and an important nutrient resource in arid regions.

Introduction

Asia is one of the most important regions of the world in the context of atmospheric aerosol loading because of the presence of growing economies in China, India and other Asian countries [1]. Industrialization, urbanization, economic growth and associated increasing energy demands have resulted in profound deterioration of urban air quality [2], [3]. Anthropogenic activities have greatly increased the emissions of reactive nitrogen (Nr) species [4], with a consequent increase in atmospheric deposition of Nr species. Elevated N deposition induced by human activities will contribute to a number of negative effects such as declining biodiversity, indirect emission of N2O, eutrophication of aquatic ecosystems and soil acidification [5][7]. Sutton et al. [8] recently estimated the total annual cost of excess Nr in the European Union to be from 70 to 320 billion euros. Excess Nr deposition has therefore become an important public concern due to its close relationship with human health, biodiversity and climate change [9].

Drought is consistently predicted to become particularly severe in arid regions, and these relatively dry regions cover about 30% of the terrestrial biosphere [10] and play a significant role in the global N cycle. Urumqi is the capital city of Xinjiang Uygur Autonomous Region and is located in the center of the arid regions of central Asia to the north of Taklimakan desert and to the south of Gurebantonggute desert. It is one of the most rapidly growing large cities worldwide. Moreover, the urban area of Urumqi is surrounded by the Tianshan Mountains from three directions with peaks up to 5000 m, and there is only one mouth facing north [11]. Together with rapid economic development, Chinese energy consumption has increased by 10% annually since 2000 compared to annual increases of only 4% from 1980 to 2000 [12]. The combustion of fossil fuels by industry and vehicles has produced a significant increase in air pollution in recent years, with rates of consumption of diesel oil, crude oil, raw coal and coke increasing by 12, 27, 68 and 92%, respectively [13]. Furthermore, N fertilizer application has also increased steadily since the 1980s due to the expansion of cotton and cereal/fruit/vegetable production in Xinjiang. NH3 emissions from fertilized croplands will be high due to the high N application rates and alkaline soil conditions in this region. We expect increasing atmospheric Nr pollution in this region. On the other hand, N limitation is often a primary or co-occurring factor limiting crop yields in arid regions, but atmospheric Nr deposition can be an important source of nutrients and inputs of Nr deposition have an important fertilizing effect in arid regions [14]. Nr deposition also plays an important role in the nutrient cycle of natural ecosystems or low input agriculture throughout China. For example, Liu et al. [15] estimated total N input from wet and dry deposition and found the values to be 15 Tg N yr−1 for the whole country in the 2000s, equal to about 50% of N fertilizer use nationwide. This is an important nutrient input to croplands from the atmosphere. However, very little is known about the influence of air pollutants and the dynamics of Nr dry deposition in arid terrestrial ecosystems. There have been several investigations of seasonal chemical properties of wet deposition [16], but there has been no investigation of N dry deposition in Urumqi because of the complexity of dry deposition monitoring. The current study aimed to answer three basic questions, namely the possibility of differences in ambient concentrations of Nr species between urban and suburban sites in central Asia, atmospheric Nr pollution dynamics and the relative contribution of N dry deposition to total atmospheric (wet plus dry) deposition in this arid environment.

Materials and Methods

Monitoring Sites

Urumqi covers a total area of approximately 140 km2 and is one of the most rapidly growing large cities in China whose permanent residents increased from 1.3 million (1990) to more than 2.5 million by 2008 [13]. The study was conducted at two sites, Shengdisuo (SDS) and Tufeisuo (TFS) (Fig. 1). Monthly mean air temperature, precipitation, wind speed and relative humidity from September 2009 to August 2010 in Urumqi are shown in Fig. 2, data provided by China Meteorological Administration at http://cdc.cma.gov.cn. The site at SDS (43°51′ N, 87°34′ E, 775 m a.s.l.) is located at Xinjiang Institute of Ecology and Geography, Chinese Academy of Sciences, and is an urban monitoring site which may be polluted by emissions from motor vehicles and home heating in winter. The site at TFS (43°56′ N, 87°28′ E, 576 m a.s.l.) is located at an experimental farm of Xinjiang Academy of Agricultural Sciences and is a suburban monitoring site which may be polluted by emissions from ammonia in agricultural fields and the use of coal for heating in winter. The distance between the two sites is about 11 km.

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Figure 1. Distribution of two monitoring sites in Urumqi, central Asia.

https://doi.org/10.1371/journal.pone.0067018.g001

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Figure 2. Air temperature, precipitation, wind speed and relative humidity from September 2009 to August 2010 in Urumqi.

https://doi.org/10.1371/journal.pone.0067018.g002

Sampling Procedure and sample Analysis

1. NH3 and NO2.

NH3 and NO2 samples were collected using Radiello® passive samplers (Aquaria Italy, Trident Equipments Pvt. Ltd., Mumbai, India). Three NH3 and three NO2 samplers per site at each period were exposed in a PVC shelter (2 m above the ground) which protected the samplers from precipitation and direct sunlight. The NH3 and NO2 concentrations at both sites were measured monthly by exposing the samplers for two weeks in the middle of each month. After sampling, absorption cartridges of the passive samplers were placed in airtight plastic tubes and stored in a refrigerator at 4°C until analysis with an automated segmented flow continuous flow analyzer (Seal AA3, Norderstedt, Germany) within two months. Detailed information about the passive samplers has been provided by Shen et al. [17]. NH3 data were collected from September 2009 to August 2010 and NO2 data were collected from February 2010 to December 2011 at both sampling sites (there was no sampling in January 2011 at the TFS site).

2. HNO3.

HNO3 vapour was measured with an active DELTA (DEnuder for Long Term Atmospheric sampling) system designed by the Centre for Ecology and Hydrology, Edinburgh, UK. Samplers for HNO3 were coated with a solution of 1% (m/v) K2CO3 and 1% (m/v) glycerol in methanol and were 15 cm in length. The sampling period was usually one month with a sampling rate of 0.35 L min−1. After exposure, the denuders were extracted in 10 mL 0.05% H2O2 solution and analyzed for NO3 using ion chromatography (DX-120, Dionex, Sunnyvale, CA). Because of the lack of suitable instruments, HNO3 (vapor) was measured only at TFS from November 2010 to October 2011.

3. PM10, pNH4+ and pNO3.

Airborne PM10 particles were sampled using a particulate sampler (BGI, Omni, Waltham, MA) with a flow rate of 5 L min−1 and 7–10 daily samples of PM10 were collected per month at each site. The sampler was placed about 2 m above the ground and ran for 24 h to obtain a particulate matter sample on 47 mm quartz filters (Whatman, Maidstone, UK). Before and after sampling, each filter was conditioned for at least 24 h inside a chamber at a relative humidity of 50% and a temperature of 25°C and then weighed (Sartorius, Göttingen, Germany; precision: 1 µg). PM10 mass concentrations were determined from the mass difference and the sampled air volume. Each sampling filter was extracted with 10 ml deionized water by ultrasonication for 30 min and the extract solution was filtered through a syringe filter (0.45 mm, Tengda Inc., Tianjin, China) and stored in a refrigerator. Chemical analysis of PM10 was conducted within two months. Ammonium and nitrate in PM10 (pNH4+ and pNO3) were measured by continuous flow analyzer (Seal AA3). PM10 (atmospheric particulate matter having an aerodynamic diameter smaller than 10 µm, which is an air-suspended mixture of solid and liquid particles that vary in size, shape, and chemical composition), NH4+ and NO3 concentrations in PM10 (pNH4+and pNO3) were collected from September 2009 to August 2010 at both sampling sites.

4. NH4-N and NO3-N in precipitation.

Precipitation samples were collected daily with stainless steel buckets (SDM6A, Tianjin Weather Equipment Inc., China) at both sites and stored in clean plastic bottles immediately after each precipitation event, then immediately placed in a freezer until analysis of NH4-N and NO3-N by continuous flow analyzer (Seal AA3) within two months. The stainless steel buckets were cleaned with deionized water before rain/snow collection to avoid contamination and dry deposition. Wet deposition fluxes of NH4-N and NO3-N were calculated using the N concentrations and the amount of precipitation for each event [18].

QA (Quality Assurance) and QC (Quality Control) are strictly guaranteed in our laboratory as part of the Key Laboratory of Biogeography and Bioresource in Arid Land, Xinjiang Institute of Ecology and Geography, Chinese Academy of Sciences. We used both standard samples and blank samples to control both QA and QC in our study.

Statistical Analysis

Values of NH3, NO2, PM10, pNH4+ and pNO3 concentrations each month at both sites are means ± standard errors (s.e.). Spearman rank correlation analysis at a significance of 99% between N species and air temperature, precipitation, wind speed and relative humidity was calculated. Differences in Nr species between the two sites were assessed by two–independent–samples test (if p<0.05 or 0.01). All statistical analysis was performed using SPSS 11.0 (SPSS, Inc. 2001). Dry deposition fluxes of NH3, NO2, pNH4+, pNO3 and HNO3 were then calculated using the N concentrations and their deposition velocities taken from the literature [19] and these deposition velocities of Nr species being average values in different ecosystem types in China. Wet deposition fluxes of NH4-N and NO3-N were calculated using the N concentrations and the amount of precipitation for each event by the following equations: N deposition per event (g N ha−1) = precipitation (mm)×NH4-N or NO3- (N concentration in precipitation) (mg N L−1)×10, N deposition per month (kg N ha−1) = ∑0.001×N deposition per event in a month [18]. All abbreviations for notations are summarized in Table 1.

Results

Concentrations of Nr Compounds in Air

1. NH3 concentrations.

NH3 exhibited distinct and significant temporal variation with lower concentrations in winter time (from December to March) than from April to October at both sites (Fig. 3a). Monthly mean NH3 concentrations varied within the range 1.6 to 9.9 µg N m−3 at SDS and 1.9 to 12.5 µg N m−3 at TFS. The annual average NH3 concentration was 6.5 µg N m−3 at SDS and lower than TFS (7.6 µg N m−3). The comparison of monthly mean concentrations between sites indicates no significant difference (p>0.05, two–independent–samples tests). NH3 concentration showed significant positive correlations with air temperature at SDS and TFS (r = 0. 832 and 0.879, both p<0.01) and negative correlations with relative humidity at TFS (r = −0.833, p<0.01).

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Figure 3. Monthly mean concentrations of (a) NH3, (b) NO2, (c) HNO3, (d) PM10, (e) NH4+ in PM10 and (f) NO3 in PM10 at SDS and TFS from September 2009 to August 2010.

https://doi.org/10.1371/journal.pone.0067018.g003

2. NO2 concentrations.

Monthly mean NO2 concentrations ranged from 14.0 to 57.3 µg N m−3 at SDS and from 6.2 to 39.5 µg N m−3 at TFS (Fig. 3b). Two–independent–samples tests indicate that NO2 concentrations at SDS were significantly higher than at TFS (p<0.01). The annual average NO2 concentration was 32.3 µg N m−3 at SDS, which was higher than at TFS (20.9 µg N m–3). NO2 concentration showed no significant correlations with air temperature, relative humidity, wind speed or precipitation at either site (both p>0.05).

3. HNO3 concentrations.

Monthly mean concentrations measured for HNO3 are given in Fig. 3C. The values range from 1.4 to 4.1 µg N m−3 at TFS. The average concentration was 2.4 µg N m−3. The HNO3 concentrations show lower values in summer than in winter, autumn or spring.

4. PM10 concentrations.

Monthly mean PM10 concentrations ranged from 72.6 to 415.4 µg m−3 at SDS and from 117.6 to 335.8 µg m−3 at TFS (Fig. 3d). The comparison of monthly mean concentrations between sites indicates no significant difference (p>0.05). PM10 concentrations reached their highest values in February (415.4 µg m−3) at SDS and in January (335.8 µg m−3) at TFS, and the concentrations showed lower values during summer and autumn at both sites. The annual average PM10 concentrations were 176.9 and 188.8 µg m−3 at SDS and TFS. PM10 concentrations were strongly or weakly correlated to air temperature (r = −0.831, p<0.01 and −0.589, p<0.05), pNH4+ concentrations (r = 0.754 and 0.709, both p<0.01) and pNO3 concentrations (r = 0.895 and 0.782, both p<0.01) at SDS and TFS, respectively.

5. pNH4+ concentrations.

Monthly mean concentrations of pNH4+ ranged from 0.1 to 23.2 µg N m−3 and from 0.2 to 22.7 µg N m−3 at SDS and TFS, respectively (Fig. 3e). The comparison of monthly mean concentrations between sites indicates no significant difference (p>0.05). The annual average pNH4+ concentrations were 7.9 and 5.3 µg N m−3 at SDS and TFS, respectively. The pNH4+ concentrations indicate that particulate ammonium concentrations peaked during winter months (20.4–23.2 µg N m−3) at SDS and reached minimum values in summer (0.2–0.4 µg N m−3) at TFS. The pNH4+ concentrations were correlated to air temperature (r = −0.951 and −0.870) and relative humidity (r = 0.868 and 0.905) at SDS and TFS, respectively.

6. pNO3 concentrations.

Monthly mean concentrations of pNO3 ranged from 0.7 to 5.1 µg N m−3 at SDS and 0.8 to 5.5 µg N m−3 at TFS (Fig. 3f). The comparison of monthly mean concentrations between sites indicates no significant difference (p>0.05). The annual average pNO3 concentrations were 2.5 and 2.8 µg N m−3 at SDS and TFS, respectively. The pNO3 concentrations indicate that particulate nitrate concentrations reached their highest values in February (5.1 µg N m−3) at SDS and in December and January (5.5 µg N m−3) at TFS.

Concentrations of Inorganic N Species in Precipitation

1. NH4– N concentrations.

Monthly mean concentrations of NH4–N in precipitation ranged from 0.2 to 2.4 mg N L−1 at SDS and from 0.6 to 4.9 mg N L−1 at TFS (Fig. 4a). Annual mean NH4– N concentrations were 1.3 and 2.2 mg N L−1 at SDS and TFS, respectively. Paired–samples t-test (95% confidence interval) indicates that the NH4–N concentration at SDS was significantly lower than that at TFS.

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Figure 4. Monthly mean concentrations of (a) NH4-N, (b) NO3-N in precipitation and wet deposition fluxes of (c) NH4-N and (d) NO3-N at SDS and TFS from September 2009 to August 2010.

https://doi.org/10.1371/journal.pone.0067018.g004

2. NO3– N concentrations.

Monthly mean concentrations of NO3– N in precipitation ranged from 0.1 to 3.1 mg L−3 at SDS and from 0.4 to 2.1 mg L−3 at TFS (Fig. 4b). The monthly mean NO3– N concentrations at both sites showed no significant difference (p>0.05, paired samples t-test). The annual average NO3– N concentration was 1.0 mg N L−1 at both SDS and TFS. The higher NO3–N concentrations measured at SDS and TFS occurred mostly in summer and autumn.

Dry and Wet Deposition of Inorganic N

Dry deposition fluxes of Nr species NH3, NO2, HNO3, pNH4+ and pNO3 were estimated by the measured Nr concentrations and their deposition velocities taken from the literature (Table 2). The deposition fluxes of NH3, NO2, pNH4+ and pNO3 averaged 6.2, 5.9, 9.2 and 3.7 kg N ha−1 yr−1, respectively, across the two sites. The deposition flux of HNO3 was 13.4 kg N ha−1 yr−1 at TFS. Monthly mean wet deposition values of NH4-N and NO3-N at both sites are shown (Fig. 4c, 4d). Annual wet deposition fluxes of NH4-N were 3.6 and 6.2 kg N ha−1 yr−1 and those of NO3-N were 2.4 and 2.6 kg N ha−1 yr−1 at SDS and TFS, respectively. Mean inorganic N wet deposition was 7.4 kg N ha−1 yr−1 across the two sites. Because there was no measurement of HNO3 at SDS, as a first approximation we assume the HNO3 concentration to be the same at both sites. Total dry and wet N deposition rates were up to 46.7 and 44.8 kg N ha−1 yr−1 at the urban (SDS) and suburban (TFS) sites.

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Table 2. Dry and wet N deposition fluxes at SDS and TFS from September 2009 to August 2010.

https://doi.org/10.1371/journal.pone.0067018.t002

Discussion

Seasonal Variation in Atmospheric Nr Concentrations

The NH3 concentration was lower in winter than other times of year at both sites and this is consistent with results reported from the North China Plain [20]. This is most likely due to high NH3 emissions from N fertilizer application, rapidly increaing livestock production, and motor vehicles. In north and northwest China NH3 concentrations are relatively high in spring and summer mainly due to N fertilization and higher air temperatures, both of which promote NH3 volatilization from arable soils. For example, the N fertilizer application rate is up to 240 kg N ha−1 per crop to achieve high yields in spring and summer at suburban parts of Urumqi. However, less than 30% of applied N fertilizer was taken up by the crops [21] and much of the unaccounted-for fertilizer N was lost by NH3 emissions. This may be an important reason for high NH3 concentration in rural or suburban area. Source strength and removal efficiency can explain seasonal variation in NH3 concentrations [22]. During warm months NH3 emissions will be promoted from other sources such as animal stables, domestic toilets and fertilized soils. Therefore, NH3 concentrations were higher at TFS (suburban) than SDS (urban) in summer. Because of zero fertilizer application and the very low air temperatures in winter, NH3 concentrations were low at both sites. Moreover, the contribution of motor vehicles to NH3 emissions is negligible in suburban areas where agriculture is the main source of NH3, while motor vehicles can be main sources of ammonia in the urban environment [23]. In the current study NO2 concentrations exhibited distinct and significant temporal variation, with higher concentrations between February and March at both sites. These NO2 values were very similar to the high concentrations observed in other regions of China [17], [24]. The area of Urumqi is only 140 km2 with a population of 2.2 million and the total number of motor vehicles in the city was 140,000 units in 2003. However, motor vehicles had reached 240,000 units and were increasing at a rate of 260 units per day since 2009. Vehicular emissions contribute significantly to air contamination in urban areas and heavy-duty vehicles are the main contributors to particle and NOx emissions [25]. For example, NOx emissions in the urban area (SDS) were mainly from heavy duty passenger buses, which comprised approximately 41.3% of total vehicle numbers, including passenger cars, buses, motorcycles, and trucks [26]. Therefore the higher NO2 concentrations are likely related to anthropogenic sources such as vehicle emissions at the urban site. In addition, the use of coal for heating in Urumqi city in winter could be the main explanation for the increased NOx concentration in the atmosphere. Other factors such as the dry weather, temperature inversion and low wind speed in winter will also lead to the accumulation of atmospheric NOx because these conditions do not favor the transformation and diffusion of atmospheric pollutants.

HNO3 concentrations at the suburban site (TFS) in our study were much higher than at many other sites across the world. For example, the HNO3 concentration was 0.6 µg N m−3on the North China Plain [17], 0.34 µg N m−3 on an urban-facing site on Mt. Gokurakuji 0.09 µg N m−3 in Kobe city in Japan [27], [28], 0.59 µg N m−3at Montelibretti in Italy and 0.60 µg N m−3at Paterna in Spain [29]. Urumqi has some of the highest air pollution in China due to the large amounts of coal combustion for industrial development and residential heating resulting in high HNO3 concentrations. The high concentrations of NO2, NH3 and HNO3 species indicate substantial atmospheric Nr pollution in Urumqi.

The PM10 concentrations at SDS and TFS were much higher than reported from numerous other urban and suburban sites [30][32] but lower than the values from Lanzhou, a city with some of the highest air pollution worldwide with a peak PM10 concentration (541.9 µg m−3) occurring in April due to dust events [33] and Tazhong area in the Taklimakan Desert [34]. The highest PM10 concentrations occurred in winter due to domestic heating in Urumqi. In addition, fireworks are a traditional way to celebrate the Chinese New Year (Spring Festival, in January or February) and may increase some pollutant concentrations in aerosols during the Spring Festival period [35]. Moreover, increasing numbers of vehicles, low wind speed and high humidity in winter (Fig. 2) have resulted in considerable PM10 pollution in Urumqi. For example, vehicle emissions have become a major source of PM in Urumqi due to a rapid growth in vehicle population over the past ten years. PM emissions in the urban area (SDS) were mainly from heavy duty trucks, which comprised approximately 46.6% of total of vehicle numbers, gasoline and diesel engine vehicles and traffic density also contributed to particle and NOx emissions, gasoline engine vehicles comprising approximately 64% of total vehicle numbers in Urumqi [26], and diesel vehicles in urban areas across Europe are equipped with exhaust after-treatment systems which reduce the total mass of emitted particles [36]. Therefore, to protect human health in urban regions we should control vehicle emissions as the highest priority [37]. The pNH4+ concentrations at the both sites were much higher than those at many other urban and suburban sites [38][40]. This was most likely generated from coal combustion in winter and from other anthropogenic sources such as vehicles, manufacturing and industrial processes at other times of year. Although wind speed varied slightly between seasons, other meteorological parameters such as low temperature and high relative humidity point towards poor dilution of pollutants during the winter period. Regarding the presence of nitrate associated with ammonium, it was more likely to form secondary particulate ammonium nitrate during the cold and humid periods in Urumqi. The pNO3 concentration was correlated to the pNH4+ concentration at the urban site (r = 0.680, p<0.05). Moreover, most anions and cations in PM10 originate from coal combustion in winter, indicating increasingly anthropogenic induced aerosols to be concentrated in Urumqi [16].

Such high Nr dry concentrations (39.0–51.6 µg N m−3) at SDS and TFS reflect serious air pollution due to increased emissions by traffic, industry and domestic heating which affect the eutrophication of water bodies and soil acidification in neighboring natural and semi-natural ecosystems, but the Nr compounds may make a substantial contribution to nutrient budgets in some intensively managed croplands [41] or in some low input agroecosystems. N inputs from wet and dry deposition are estimated at 15 Tg N yr−1 for the whole of China in the 2000s and about 5.0 Tg annual N deposition may have returned to croplands in China since the 2000s [15]. This is an important nutrient input to croplands from the atmosphere.

Inorganic N Concentrations in Precipitation

It is generally thought that the major anthropogenic source of NH4+ in precipitation is NH3 volatilized from N fertilizers and the excrement of human beings and animals, major anthropogenic sources of NO3 are NOx emitted from fossil fuel combustion from power plants, automobiles, and biomass burning [42]. In the present study the higher NH4-N concentrations at the suburban site (TFS) and higher NO3-N concentrationsat the urban site (SDS) were found in summer and early autumn (Fig. 4), reflecting the effects of both agricultural and non-agricultural (e.g. traffic and industrial) Nr sources. In recent years motor vehicles have become important sources of ammonia from cars and other vehicles with catalytic converters emitting large amounts of NH3 [43] and this might increase NH4+ concentrations in precipitation as NH3 can transform to pNH4+. We found significant positive correlations between NO3 and NH4+ in precipitation at SDS (r = 0.583, p<0.05) and TFS (r = 0.736, p<0.01), suggesting similar origins for a substantial component of the ammonium- and nitrate-N. The ratio of NH4-N to NO3-N (expressed as NH4-N/NO3-N) was calculated to analyze the source information on the wet deposition in this study area. In general, the ratio of NH4-N to NO3-N reflects the relative contribution of Nr from industry and transportation, agriculture, and animal husbandry to N deposition on a local scale [44], NH4-N/NO3-N is usually much smaller than 1 in industrialized regions and the ratio is usually greater than 1 in intensive agricultural regions [45]. We found annual average NH4-N/NO3-N values of 1.3 and 2.2 at SDS and TFS and this indicates that NH4-N concentrations in precipitation are likely be largely influenced by agriculture and human and animal excrement, NH3 may remain the major contributor to wet N deposition in our study area, especially at the suburban site, compared with the NO3-N mainly from fossil fuel combustion in industry and transportation [46].

Fluxes of Dry and Wet Deposition of Inorganic N

The mean NH3 deposition flux in Urumqi was 6.2 kg N ha−1 yr−1, which was lower than the mean value (18.4 kg N ha−1 yr−1) on the North China Plain [20]. Mean NO2 deposition flux in Urumqi averaged 5.9 kg N ha−1 yr−1, which is slightly higher than the average value (3.03 kg N ha−1 yr−1) for China [47] but much lower than the reported value (17.3–30.7 kg N ha−1 yr−1) on the North China Plain [17]. The total particle N deposition fluxes (pNH4+ and pNO3) were 14.4 and 11.2 kg N ha–1 yr−1 at SDS and TFS. Our results are similar to those on the North China Plain (8.4–14.2 kg N ha−1 yr−1) [17] and a suburban region of Gpoalpura in India reported by Satsangi et al. [48] but higher than in Thessaloniki city in Greece (0.99 kg N ha−1 yr−1) [49] or Al-Hashimya city in Jordan (0.76 kg N ha−1 yr−1) [50].

In the present study the wet deposition fluxes (7.4 kg N ha−1 yr−1 on average) were relatively low compared to those reported for other areas in China. For example, wet deposition fluxes of inorganic N were 24–27 kg N ha−1 yr−1 in east China [51] and 27–30 kg N ha−1 yr−1 on the North China Plain [18], [52]. Lu and Tian [47] reported an average value of 9.9 kg N ha−1 yr−1 in China. The relatively low wet deposition of inorganic N in Urumqi may have been largely due to the low precipitation in this arid region, with mean annual precipitation of about 259 mm from 1960 to 2004 [53]. Ratios of NH4-N to NO3-N in precipitation (1.3 and 2.2 at SDS and TFS, respectively) clearly show the impacts of agricultural (suburban site) and non-agricultural (urban site) sources on wet deposition of N, and further reflects the effects of NOx emissions from industry and transportation in urban areas (Pan et al., 2012) [46]. Moreover, dissolved organic N comprises approximately 30% of total N deposition [54], but organic N in wet deposition was not considered in this study. To obtain more accurate estimates of the wet N deposition in this study area it will be necessary to analyze the organic N concentrations., The total N depostion (dry and wet) fluxes were systematically evaluated in this study. Whereas previous studies only focused on the wet deposition (Xu et al., 2008) [16] and the dry deposition of HNO3 and Nr species were not measured. Total N deposition (dry and wet) fluxes were 46.7 and 44.8 kg N ha−1 yr−1 at the urban and suburban sites in Urumqi, with a mean value of 45.8 kg N ha−1 yr−1. Such deposition rates are somewhat higher than the critical load of N for sensitive ecosystems (e.g., 5–10 kg N ha−1 yr−1) according to Bobbink and Roelofs [55]. We found the proportion of Nr dry deposition in total deposition to be up to 80.6%, much higher than in other humid regions worldwide [56]. Nr dry deposition is a very sensitive index for croplands, grasslands, forests and aquatic ecosystems and it reflects atmospheric pollution levels, while processes that control N deposition velocities include gravitational settling, impaction, and diffusion, processes which act simultaneously and are affected by many variables including particle size, wind speed, relative humidity, and land surface roughness [57]. Because of the difficulty in obtaining in-situ dry deposition velocities of Nr species [58], we used simplified deposition velocities taken from the literature [19]. We are therefore aware of the uncertainty of dry deposition of inorganic N in the current study. To reduce uncertainties of N deposition, wet and dry deposition of organic N and the in-situ measurements of N dry deposition velocities merit evaluation in an arid region of central Asia in future studies. In addition, modeling tools are very useful for quantifying atmospheric N deposition (including both spatial and temporal variations), but model validation generally suffers from a serious lack of long-term Nr concentrations monitoring data. Therefore, modeling tools and long-term monitoring will be conducted in future studies in this region.

Conclusions and Summary

  1. Annual mean concentrations of NH3, NO2, HNO3, pNH4+, pNO3, and PM10 were 7.1, 26.6, 2.4, 6.6, 2.7 µg N m−3 and 182.9 µg m−3 across both urban (SDS) and suburban (TFS) sites in Urumqi, central Asia. The NO2, pNH4+ and pNO3 concentrations were highest during winter and the peak NH3 concentrations appeared in summer, reflecting the distinct impacts of agricultural (NH3) and non-agricultural (other Nr species) sources. Such high Nr concentrations imply serious local air pollution due to increased emissions from traffic, industry and domestic heating in winter.
  2. The annual mean NH4-N and NO3-N concentrations in precipitation were 1.8 and 1.0 mg L−1, respectively, across SDS and TFS. The higher NO3-N and NH4-N concentrations occurred mostly in summer and early autumn, and significant positive correlations were found between NO3-N and NH4-N. The annual mean NH4-N/NO3-N values were 1.3 and 2.2 at SDS and TFS, respectively.
  3. Dry deposition fluxes of NH3, NO2, HNO3, pNH4+ and pNO3 averaged 6.2, 5.9, 13.4, 9.2 and 3.7 kg N ha−1 yr−1 at the two sites with a total dry deposition flux of 38.4 kg N ha−1 yr−1. Wet deposition fluxes of NH4-N and NO3-N were 4.9 and 2.5 kg N ha−1 yr−1 across both suburban and urban sites in central Asia. The total (dry and wet) N deposition values averaged 45.8 kg N ha−1 yr−1, with dry deposition accounting for a high percentage (83.8%) of total deposition in Urumqi in an arid environment. Such high N deposition implies that heavy environmental pollution needs to be controlled by substantially reducing the Nr emissions to the environment, but high Nr dry deposition can be used as an important agricultural nutrient resource and it should be considered in integrated N fertilizer management in arid regions.

Author Contributions

Conceived and designed the experiments: XL CT. Performed the experiments: KL WS YH YC. Analyzed the data: KL. Contributed reagents/materials/analysis tools: KL WS. Wrote the paper: KL XL.

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