Introduction

Rapid industrial development and agricultural production emit large quantities of NOx (NO + NO2) and NH3 to the atmosphere1,2. After a series of chemical transformations and physical transport processes in the atmosphere, NH3 and NOx are removed through dry deposition and wet scavenging and deposited on the Earth’s surface3,4. Due to the ease of observation, wet nitrogen (N) deposition has been widely and intensively researched5,6. However, growing evidence suggests that dry N deposition is also an important component in total N deposition. For example, Pan et al. reported that dry deposition represents approximately 60% of the annual total deposition, according to the average results of ten sites in northern China7. Gaseous N and particulate N (two forms of dry deposition) can cause a series of biochemical reactions after they penetrate leaves through plant stoma or directly enter the soil8. These reactions then affect the structure and function of an ecosystems9. Therefore, quantifying the spatio-temporal patterns of dry deposition is critical to comprehensively understanding the role of dry deposition in global N cycles and to providing scientific background on its ecological effects.

The methods for measuring dry deposition fluxes at the site scale include the eddy correlation method, chamber method, inferential method and gradient method10. The inferential method is currently the most common method because of its easy operation, low cost and relatively high accuracy11,12. In this method, ground air N concentrations and deposition velocities (Vd) are key factors in the calculation of dry deposition fluxes. Currently, the primary methods for sampling ground air N concentrations include filter packs, denuders and passive samplers and the chemical methods for measuring air N are the ion chromatography and spectrophotometric methods. Although many different methods for sampling and chemical measurement exist, the results from different methods are highly consistent13,14,15. Vd, the other key factor of dry deposition, is usually simulated using models such as a big leaf model16,17,18 and the Multi-Layer Model19. The observation of sites in different regions worldwide provides the basis to evaluate and validate N deposition at global or regional scales2,18.

The main methods for evaluating dry deposition fluxes at regional or global scales are geostatistical methods and model simulation. For example, the geostatistical method has been used to evaluate the spatial patterns of dry deposition in Europe, the United States and China5,18; Dentener et al.3 and Vet et al.2 simulated global total N deposition including dry and wet forms based on multiple atmospheric chemistry transport models. Recently, a new method was developed to study the spatial pattern of dry deposition by applying satellite observations20,21. Cheng et al. used Global Ozone Monitoring Experiment (GOME) and Scanning Imaging Absorption Spectrometer for Atmospheric Chartography (SCIAMACHY) observations to determine the spatial and temporal characteristics of NO2 dry deposition based on the empirical relationship between NO2 columns and rural NO2 in situ measurements in eastern China20. Nowlan et al. characterized global NO2 dry deposition fluxes using satellite measurements from the Ozone Monitoring Instrument (OMI) in combination with simulations from the GEOS-Chem model21. This new method features certain major advantages: First, satellite observations can be used to evaluate spatially and temporally continuous NO2 fluxes20,21. Second, these observations can provide results with a higher spatial resolution than model simulations at the global scale21. Third, fewer parameters are needed in this method than in the model simulations20. Consequently, it is worthwhile to develop a theory and methodology for evaluating the spatio-temporal patterns of global dry deposition using satellite observations.

This study compiled a worldwide dataset of atmospheric inorganic N concentrations from 555 ground monitoring sites (Fig. 1), including 7,424 site-year data, downloaded OMI NO2 column standard products between 2005 and 2014 and data on dry deposition velocities from 163 sites worldwide. Based on the chemical transformations between airborne reactive N, we developed methods that can, for the first time, determine the 2005—2014 global patterns and trends in dry deposition fluxes directly from ground- and space-based data.

Figure 1
figure 1

Global distribution of monitoring sites for atmospheric inorganic N concentrations.

Note: At least one species of inorganic N was measured at each site. The map was generated using ArcGIS 10.0 software.

Results

Spatial patterns of global dry N deposition fluxes

The magnitude and spatial patterns of global dry deposition fluxes differed significantly by region and N species (Fig. 2). In summary, eastern China, Western Europe and the eastern United States were the three global hotspots for NO2, HNO3, NH4+ and NO3 fluxes. According to the site results for NH3 fluxes (Fig. 2e; for details, see Methods), high flux values occurred in China, India and North Africa, whereas lower flux values were present in Europe and the United States. The global averages of the NH3, NO2, HNO3, NH4+ and NO3 fluxes were 1.64, 0.45, 0.27, 0.11 and 0.02 kg N ha−1 a−1, respectively. The highest values for total N fluxes, including five N species and with values of approximately 50–55 kg N ha−1 a−1, occurred in eastern China.

Figure 2
figure 2

Spatial patterns of dry N deposition fluxes (kg N ha−1 a−1) for (a) NO2, (b) HNO3, (c) NH4+, (d) NO3 and (e) NH3. The NH3 fluxes were derived from 267 monitoring sites (see Methods). The maps were generated using ArcGIS 10.0 software.

Trend analysis of global N dry deposition fluxes

The average annual changes in the dry deposition fluxes (the sum of the NO2, HNO3, NH4+ and NO3 fluxes) ranged from −1.9 to 2.0 kg N ha−1 a−1 between 2005 and 2014, with a global mean value of 0.018 kg N ha−1 a−1 (Fig. 3). These results indicated that the dry deposition fluxes increased or decreased in some regions annually and exhibited a weak positive trend worldwide. The significant increases were located in the western United States and Eurasia, particularly eastern China and the significant decreases occurred in the eastern United States, Western Europe and Japan. Globally, HNO3 was the most abundant N species in the dry deposition flux increases because of its high deposition velocity, followed by NO2, NH4+ and NO3.

Figure 3
figure 3

The average annual changes in dry N deposition fluxes (kg N ha−1 a−1).

Note: The slope was calculated by plotting annual dry deposition fluxes against time from 2005 to 2014 in each grid and the slope value was used to represent the annual change rate. Due to the lack of continuous data for NH3 fluxes, the trend analysis of dry deposition only included annual changes of NO2, HNO3, NH4+ and NO3 fluxes. The map was generated using ArcGIS 10.0 software.

Global and regional total dry N deposition

Table 1 shows the global and regional total dry deposition. Based on the results inferred from the OMI NO2 columns, NO2 was the most abundant N species in dry deposition globally, followed by HNO3, NH4+ and NO3. Asia and Africa received the largest volume of deposition, based on the sum of these four N species (“Subtotal” in Table 1), followed by North America, South America, Europe and Oceania. Asia and Africa were also the regions with the greatest deposition based on a single N species.

Table 1 Global and regional dry deposition (Tg N a−1).

In the present study, the regional deposition of NH3 was calculated as the product of the averaged fluxes based on site measurements and a regional area. Because crop sites represented a large portion of the collected NH3 sites (approximately 1/3), the regional NH3 deposition results in this study may be overestimated. According to our results (Table 1), the global deposition of NH3 was 22.28 Tg N a−1 and Asia and Africa were the regions with the greatest deposition, followed by South America, North America, Europe and Oceania. Summing all five N species, the global total deposition was approximately 34.26 Tg N a−1.

Discussion

Dry deposition and dry/wet deposition ratios from different studies

Studies on dry deposition at a large scale are still limited and they have primarily focused on regions with high N deposition, i.e., the United States, Europe and China. The results of this study and previous studies on both global- and regional-scale dry deposition are listed in Table 2. Our results are comparable to previous studies and the large-scale dry deposition results that differ are on the same order of magnitude (Table 2). Additionally, certain differences exist among the results from different methods because each method has its own uncertainty. The uncertainty in the atmospheric chemistry transport models is primarily derived from the assessment of NOx and NH3 emissions and the dry deposition parameterizations2,3. The accuracy of geostatistical methods depends on the number, distribution and types of monitoring sites5,18. However, globally, N deposition monitoring sites are still rare except in Europe, North America and Asia2. The method used in the present study is based on data from ground and satellite measurements and the uncertainty in this method arises from these two data sources. Although all types of methods have their own uncertainties, the development of multiple methods will make the evaluation of dry deposition more accurate and comprehensive. Compared to other methods, the method used in this study has two advantages. First, this method has a simpler structure and requires fewer parameters, which reduces computation time and decreases uncertainty associated with the multiple data sources. Second, this method can conveniently provide continuous results for trend analysis of dry deposition.

Table 2 Comparison of global and regional N deposition from different studies (Tg N a−1).

Based on previous studies of wet deposition (Table 2), we calculated dry/wet deposition ratios in the United States, Europe and China and found the average ratios to be 0.93, 0.55 and 0.56, respectively. In the United States, Europe and China, dry deposition contributed 48%, 35% and 36% to total deposition, respectively. Vet et al. estimated that the global total deposition was 79.5 Tg N a−1 based on multiple models2. However, they did not note the specific value of dry deposition. If we assume that 40% of the total deposition is deposited via dry deposition, then the global dry deposition would be 31.8 Tg N a−1 according to the total deposition result from Vet et al. This value is close to our result of 34.26 Tg N a−1. The above analysis corroborated dry deposition’s important role in global N deposition. However, the majority of ecological field experiments on N enrichment to date have focused on wet deposition fluxes; therefore, the investigation of how dry deposition affects ecosystem structures and functions is an important ecological issue.

Key hotspots of dry deposition changes

According to the results of our trend analysis between 2005 and 2014 (Fig. 3), the eastern United States, Western Europe and Japan show a clear declining trend in dry deposition, corresponding to monitoring site reports from the United States and Europe6,22. These findings suggest that dry deposition is still high in these regions but has declined significantly in recent years. As a result of the Cross-State Air Pollution Rule, NOx emissions from electrical generation are expected to have decreased by over 50% from 2005 to 2014 in the eastern United States23. In the 28 EU countries, NOx emissions and NH3 emissions decreased on average 51% and 28%, respectively, from 1990 to 2012 through the control of air pollution emissions22. These policy examples suggest that N deposition can clearly be decreased by controlling NOx and NH3 emissions, which is important for weakening the potential detrimental effects of N saturation on ecosystems24,25,26.

In sharp contrast to the above regions, eastern China not only experienced high dry deposition fluxes but also featured the greatest increase in dry deposition fluxes over the past decade (Fig. 3) and the most expected hotspots of N deposition. These results agree with the continuous measurements of wet and dry deposition at ten sites in this area7. According to those results, the total N deposition at the ten sites ranged from 28.5 to 100.4 kg N ha−1 a−1, with an average value of 60.6 kg N ha−1 a−1. Of this total, 40% was deposited via precipitation and the remaining 60% was deposited by dry deposition. Large NOx and NH3 emissions are the reason for the ongoing high N deposition in this region. Between 1980 and 2010, NOx and NH3 emissions in China grew approximately linearly and increased from 1.4 to 6.3 Tg N a−1 and from 5.7 to 14.5 Tg N a−1 (ref.27), respectively, resulting in inevitably high quantities of deposited N. Although N deposition can increase ecosystem carbon sequestration to a certain extent28, excessive N results in negative impacts on soil, water and biological diversity24,25,26. In recent years, worsening smog-related weather conditions in China have created a threat to public health and the Chinese government enacted pollution control and management regulations and strengthened measures to control pollutant emissions. N deposition is expected to decrease with the promulgation and implementation of these regulations.

Scientific basis for establishing remote sensing empirical models

In this study, we established remote sensing empirical models to estimate ground NO2, TNO3 (the sum of HNO3 and NO3) and NH4+ concentrations using OMI satellite measurements and ground measurements. Although they are empirical models, there is a scientific basis for establishing them. The logical framework for the method of determining dry N deposition is shown in Fig. 4.

Figure 4
figure 4

Logical framework for the method used to determine dry N deposition and atmospheric N-related processes, including N emissions and chemical transformation processes.

Based on chemical transformations between inorganic N species, the OMI NO2 columns were used to estimate the ground concentrations of NO2, TNO3 (HNO3 + NO3) and NH4+ by establishing remote sensing empirical models and then dry deposition fluxes were calculated using the inferred method. Note: The red arrows represent N emissions from natural and anthropogenic sources; the black arrows represent the chemical transformation processes between atmospheric inorganic N species, which are discussed in the literature4,10; the solid and dotted black arrows are the primary and secondary processes, respectively; the blue arrows represent the logical framework for the evaluated method in this study; and the symbols “F”, “C” and “Vd” represent dry deposition flux, ground concentration and deposition velocity of inorganic N species, respectively.

Blond et al. noted that NO2 ground measurements performed in urban areas cannot be used to validate remote sensors with relatively low spatial resolutions due to strong concentration gradients in urban areas29. However, NO2 ground concentrations at rural sites, where measurements can represent large areas, are significantly positively correlated with NO2 columns. Based on this positive correlation, Cheng et al. established a remote sensing empirical model to estimate NO2 dry deposition in eastern China20. We improved Cheng’s model by developing a global NO2 model and modifying the parameterization and validation methods.

When NO2 is released into the atmosphere, it is converted into gaseous HNO3 or particulate NO3 (ref. 4). The conversion processes of NO2 to HNO3 or NO3 and the processes of mutual conversion between HNO3 and NO3 are shown in Fig. 4. Because NO2 is the source of HNO3 and NO3, we inferred that a positive relationship should exist between the number of sources and sinks and our study demonstrated this assumption. We tested the relationships using data from monitoring sites observing the concentrations of NO2, HNO3 and NO3 and found that NO2 concentrations have a strong positive correlation with the sum of HNO3 and NO3 concentrations (Supplementary Fig. S1). This is the scientific basis of the TNO3 model.

In this study, the NH4+ model was the result of an initial attempt, but validation subsequently indicated that this model is reliable. We surmise that this model can evaluate ground NH4+ concentrations using NO2 columns because NH4NO3 is the main form of NO3 in aerosols and because NO2 is the source of the NO3 in NH4NO3 (see Fig. 4). Thus, a strong linear positive correlation exists between NH4+ and NO3 concentrations30. Additionally, we also attempted to establish an NH3 model using NO2 columns, but the result was not satisfactory. The main reason for this is that NH3 and NO2 come primarily from agricultural and industrial activities, respectively; thus, no restrictive relationships exist in their chemical transformation due to their different sources.

Uncertainty analysis

Although our findings are reliable based on the site data validation (see Supplementary Fig. S2), they are still uncertain to some extent. There are four possible contributors to the uncertainty. First, some error is from the OMI NO2 column products, derived mainly from the calculation of air mass factors (AMF) and the uncertainty in the AMF is approximately 10–40% (ref.31). Second, error may come from ground monitoring data. The monitoring data collected in this study were derived from different monitoring networks or the literature and some errors may arise from researchers using different methods of sample collection and different measuring instruments. Third, some uncertainties are attributed to the estimation of deposition velocity and previous studies have suggested that there is great uncertainty in this estimation11,18. Here, we attempt to reduce this uncertainty by collecting deposition velocity values from the published literature instead of calculating them directly. Furthermore, the regional assessment of NH3 deposition in our study contains uncertainties. The regional deposition of NH3 was calculated from the site-based NH3 fluxes averaged over the region and crop sites represented a large proportion of the collection sites (approximately 1/3). Thus, the regional results of NH3 deposition in this study may be overestimated. We note that NH3 columns were retrieved from the IASI satellite32,33 and we expect that it can be used to calculate NH3 ground concentrations in the future. This calculation will be helpful in evaluating spatial patterns of ground-level NH3 concentrations more precisely, thus improving the spatial resolution of NH3 dry deposition.

Methods

Ground-level in situ measurements

The atmospheric inorganic N concentration data are from three sources: results published after 2000 (see the Supplementary Information for a complete reference list), N deposition monitoring networks worldwide and the World Data Centre. Nine monitoring networks provided available data for this study: the Co-operative Programme for Monitoring and Evaluation of the Long-Range Transmission of Air Pollutants in Europe (European Monitoring and Evaluation Programme, EMEP); the Clean Air Status and Trends Network (CASTNET); the Air Quality System (AQS) and Ammonia Monitoring Network (AMoN) in the United States; the Canadian Air and Precipitation Monitoring Network (CAPMoN) and National Air Pollution Surveillance Program (NAPS) in Canada; the Acid Deposition Monitoring Network in East Asia (EANET); the Igac Debits Africa program (IDAF); and the Department of Environment and Heritage Protection of Queensland, New South Wales and Northern Territory in Australia. Currently, the most common methods for sampling ground air N concentrations include filter packs, denuders and passive samplers and the chemical methods for measuring air N are the ion chromatography and spectrophotometric methods. Although many different methods for sampling and chemical measurement exist, the results from different methods are highly consistent13,14,15. This agreement is the basis for our analysis of the global data from different studies. To study global dry deposition at the annual scale, the criteria for collecting data were as follows. First, the land use type of the monitoring site must be clearly described, e.g., forest, crop, grassland, wetland, etc. Second, we imposed no restrictions on the sampling and measuring methods, but the sampling frequency must have been on the day, week, or month scale and the sampling period must have been longer than one year. Third, the atmospheric concentrations of one or several species, i.e., NO2, NH3, HNO3, NH4+ and NO3, must have been measured. After we collected the data, certain processes were performed to make the data available, including data collation, data unit transformation and abnormal value elimination.

Our datasets included the following: the name of the monitoring site, location of the monitoring site, monitoring period, monitoring method, land use type, NO2-N concentration, NH3-N concentration, HNO3-N concentration, NH4+-N concentration, NO3-N concentration and the literature source. After rigorous data screening and quality control, we obtained a total of 555 sites and 7,424 site-year data for atmospheric inorganic N concentrations. There are 265 sites in North America, 124 in Europe, 98 in Asia, 32 in Africa, 23 in Oceania and 13 in South America and 1,588, 1,015, 1,692, 1,437 and 1,692 site-year data for NO2, NH3, HNO3, NH4+ and NO3 concentrations, respectively. The monitoring sites were distributed worldwide (Fig. 1) and among the major terrestrial ecosystems, including forest, grassland, crops, shrub, desert, wetland and tundra.

NO2 columns from the OMI satellite instrument

The Ozone Monitoring Instrument (OMI) aboard the Aura satellite was launched on 15 July 2004. Aura flies in a sun-synchronous polar orbit at an altitude of approximately 705 km with a local equatorial overpass time between 13:40 and 13:50 local time. The OMI has three spectral channels with a spectral range between 270 and 500 nm and is used to measure trace gases, including O3, NO2, SO2, HCHO, BrO and OCIO. It has a spatial resolution of 13 km×24 km and provides nearly global coverage every day. The details of the OMI can be obtained in Levelt et al.34.

NO2 vertical tropospheric columns are derived from the DOMINO v2.0 OMI NO2 product provided by the Tropospheric Emission Monitoring Internet Service (TEMIS, www.temis.nl). The details of this product can be found in Boersma et al.31. The unit of this product is 1015 molec./cm2 with a spatial resolution of 0.125° × 0.125°. In this study, we downloaded the global monthly product of NO2 columns between January 2005 and December 2014 in the format of an ESRI grid. Then, the annual NO2 column mean was calculated by averaging the monthly NO2 columns.

Dry deposition fluxes

In the inferential method12, the dry deposition flux (Fdry) is typically estimated by multiplying the atmospheric N ground concentration (C), including gaseous N and particulate N, by the deposition velocity (Vd). The Fdry can be expressed by the following equation:

Unlike other N species, NH3 presents obvious bi-directional fluxes, i.e., NH3 can be deposited from the atmosphere onto land, but it can also be emitted from the land into the atmosphere35. Thus, a gaseous NH3 “canopy compensation point” likely exists and deposition occurs only when the measured NH3 concentration is higher than the compensation point36,37. Accordingly, unlike the other four N species, the equation of Fdry for NH3 is as follows:

where C0 is the canopy compensation point of NH3. The values of C0 for various ecosystems are obtained from previous studies38,39.

According to equations (1) and (2), the calculation of Fdry for atmospheric inorganic N requires information on C and Vd.

Ground concentrations (C)

Based on global ground monitoring concentrations of atmospheric inorganic N and OMI NO2 columns, we developed remote sensing empirical models at an annual scale to determine the global ground NO2, TNO3 and NH4+ concentrations. Because we used the same modelling approach for these three N species, we describe the NO2 model as an example here. The specific approach was as follows. First, NO2 columns were extracted according to the locations of the monitoring sites using ArcGIS 10.0 software. The NO2 ground concentration at each monitoring site and the corresponding NO2 column were treated as a pair of data. Second, the linear model (y = a + bx) was selected as the regression model, where x was the NO2 column and y was the corresponding in situ NO2 ground concentration. Third, 2/3 of the pairs of data were selected to establish the model and the other 1/3 of the data was used for model validation. Statistics of fit and validation were also calculated. Fourth, the previous step was repeated 500 times through a random and non-repeated sampling method to decrease the random error due to certain fitted data and the averaged statistics were used to evaluate the fit and validation of the model.

In this study, the validation statistics included the coefficient of determination (R2), root mean square error (RMSE) and modelling efficiency (EF). The calculation and meaning of the statistics can be seen in the Supplementary Information. The final equations for estimating ground NO2, TNO3 and NH4+ concentrations are shown below (equations (3))-(5)) and the averaged statistics of model parameterization and validation are shown in Supplementary Table S1.

where [NO2]R is the OMI NO2 column data (1015 molec./cm2) and [NO2]G, [TNO3]G and [NH4+]G are the ground measurements (μg N m−3) for NO2, TNO3 and NH4+, respectively. The slope and intercept values are the averaged results of 500 circulations.

The results in Supplementary Table S1 show that our models exhibited good performance in terms of model fit and validation. For example, the values of R2 and EF were all approximately 0.70. Based on equations (3)-(5) and the NO2 columns, we estimated the global patterns of ground NO2, TNO3 and NH4+ concentrations (Supplementary Fig. S3a-c). Because no significant correlation existed between NH3 ground concentrations and the NO2 columns, we could not establish an empirical model to estimate NH3 ground concentrations globally. Instead, we collected 267 NH3 monitoring sites from the literature and monitoring networks to assess the global pattern of ground NH3 concentrations. The distribution and concentration values of the NH3 monitoring sites are shown in Supplementary Fig. S3d.

Deposition velocities (Vd)

The deposition velocities of atmospheric inorganic N are from two sources: results published after 2000 and simulated results from the CASTNET network. The primary method for estimating deposition velocities in the literature is the big leaf model and the method used in the CASTNET network is the Multi-Layer Model. A total of 163 sites containing deposition velocities were collected in this study (Supplementary Table S2). The main land uses of these sites included forest, grassland, crop, shrub, wetland, desert and water.

Previous studies have suggested that land use was the dominant factor for dry deposition velocities16,17. The results of dry deposition velocities for different forms of N in various land uses are listed in Table 3. The results from different researchers indicated that dry deposition velocities obviously differ between different land uses. Accordingly, the average deposition velocities for the five N species in various land uses were calculated. Then, the deposition velocities of the five N species were mapped to the global land cover map according to land use types (Supplementary Fig. S4). In this present study, we used a global land cover map published by the European Space Agency (Globcover 2009)40 and resampled it to 0.125°×0.125°.

Table 3 Comparison of dry deposition velocities in different land uses (cm s−1).

Calculation and validation of dry deposition fluxes (Fdry)

Based on the estimated global ground concentrations and the corresponding Vd in the above sections, we estimated the global spatial patterns of NO2, HNO3, NH4+ and NO3 fluxes using equation (1). Because of the large difference between HNO3 Vd and NO3 Vd (Supplementary Fig. S4), it was necessary to separate TNO3 concentrations into HNO3 and NO3 concentrations to calculate their fluxes. Due to an insufficient number of monitoring sites, we separated TNO3 concentrations at the continental scale using the following specific method. We calculated the average HNO3/NO3 ratio for each continent using monitoring sites with simultaneous observations of ground HNO3 and NO3 concentrations. Using the ratios and the ground TNO3 concentrations, the global ground HNO3 and NO3 concentrations were calculated. The average HNO3/NO3 ratios were 0.60, 1.72, 1.67, 1.84 and 0.66 for Europe, Asia, North America, Africa and South America, respectively. The ratio for Oceania was assumed to be 1.00 due to a lack of monitoring sites. Additionally, we calculated NH3 fluxes using equation (2) based on concentration measurements from 267 sites and their Vd values. Then, arithmetic averages were used to represent the magnitude of regional and global NH3 fluxes.

To verify the dry N deposition fluxes estimated in this study, we collected the site reported fluxes in the references or observing networks and compared the reported fluxes and corresponding simulated fluxes in this study (Supplementary Fig. S2). With the exception of NO3 fluxes, the model fluxes of NO2, HNO3 and NH4+ showed good correlation with their reported fluxes (r ≈ 0.60). The averaged model fluxes of the four N species were close to their reported fluxes. Statistically, 71%, 70%, 78% and 62% of the model fluxes agreed within ±50% of the reported fluxes for NO2, HNO3, NH4+ and NO3, respectively. Alternatively, we also noted that certain sites plotted far from the 1:1 line in the scatter plots (Supplementary Fig. S2), indicating that the model results were underestimated or overestimated to some extent at certain sites. Nonetheless, these findings demonstrated that the results of our model agree well with the majority of the reported results.

Additional Information

How to cite this article: Jia, Y. et al. Global inorganic nitrogen dry deposition inferred from ground- and space-based measurements. Sci. Rep. 6, 19810; doi: 10.1038/srep19810 (2016).