Abstract
Over the past century, atmospheric inorganic nitrogen (IN) deposition to terrestrial ecosystems has significantly increased and caused various environmental issues. China has been one of the hotspot regions for IN deposition, yet limited data exist regarding IN deposition fluxes in China at the regional scale. In this study, based on NO2 and NH3 columns acquired by satellite sensors, coupled with atmospheric chemical transport model (CTM), mixed-effects model and site observations, we constructed regional-scale IN dry and wet deposition models respectively, and finally proposed a spatially explicit database of IN deposition fluxes in China. The database includes the dry, wet and total deposition fluxes in China during 2011–2020, and the data are presented in raster form with a resolution of 0.25° × 0.25°. Overall, the database is of great importance for monitoring and simulating the trends of IN deposition over a long time series in China.
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Discover the latest articles, news and stories from top researchers in related subjects.Background & Summary
Atmospheric nitrogen (N) deposition plays an important role in the biological N cycle, with anthropogenic emissions of inorganic nitrogen (IN) returning to the surface as atmospheric deposition. The sources of N compounds are intricate. Reduced N components (NH3, NH4+, etc.) mainly originate from agricultural fertilization and animal husbandry. In contrast, oxidized N compounds (NO, NO2, NO3−, etc.) primarily come from industry and fossil fuel combustion. Considerable spatial and temporal variations exist between the two sources. The increase in N deposition in the short term can enhance the ecosystem vitality, but a large amount will inevitably have an impact on the environment. Over the past two decades, extensive scientific research on acid deposition in China has played a pivotal role in shaping national policies aimed at combating acid rain pollution. These policies primarily centred on curbing emissions of sulfur dioxide (SO2) and nitrogen oxides (NOx), which are the main contributors to acid deposition. Thanks to the effectiveness of policy development, there has been a growing international focus on nitrogen deposition in recent years. Atmospheric chemistry transport model (CTM) simulations have revealed that the areas with high N depositions in China have increased significantly over the past 40 years1, which may have negative impacts on forest, grassland, agricultural, aquatic and coastal ecosystems2.
Inorganic nitrogen deposition is mainly evaluated by three methods: ground sites monitoring, CTM simulations, and quantitative remote sensing estimation. Compared to dry deposition, the observations on wet deposition at ground sites started earlier. The earliest observations on wet depositions in China can be traced back to the national acid rain monitoring network established by the National Environment Bureau of China from 1981 to 19833. This network focused on observing acid rain, in which nitrogen wet deposition fractions (NO3− and NH4+) were measured. After that, several other networks were established successively. Most of them were concentrated in urban areas4, which cannot reveal the regional characteristics well5,6. Subsequently, the National Nitrogen Deposition Monitoring Network (NNDMN) was established by China Agricultural University, which can obtain comprehensive observations of dry and wet nitrogen deposition across China, covering farmland, grassland, woodland and urban areas7. Based on ground-based monitoring sites, the average atmospheric IN deposition flux in China ranged from 20.4 to 40.0 kg N ha−1 yr−1 during the period of 2010 to 20207,8,9.
The atmospheric CTMs, with the capability to establish a connection between nitrogen sources and sinks, are based on emission inventory and meteorological data to simulate IN deposition fluxes10. There have been several global-scale atmospheric chemistry models, such as GEOS-Chem and MOZART11. However, their coarse spatial resolution limits the ability to provide detailed information on the spatial variations of IN deposition. Furthermore, atmospheric CTMs have tended to underestimate wet deposition of nitrate-N in the Asian region12. The atmospheric IN deposition fluxes simulated by CTMs ranged from 7.9 to 18.1 kg N ha−1 yr−1 in China10,13. There existed a large gap in the estimates of IN deposition in China by CTMS and site observations. Consequently, it is urgent to develop a supplementary approach to unravel the spatiotemporal patterns of atmospheric IN at a regional scale14.
Satellite observations have the advantages of wide spatial coverage, strong periodic observation capability and high spatial resolution15. It can provide an effective method to estimate NO2 and NH3 columns16, and has been widely used to observe regional pollutant gases. Currently, satellite sensors capable of monitoring NO2 include GOME (Global Ozone Monitoring Experiment), SCIAMACHY (SCanning Imaging Absorption spectroMeter for Atmospheric CHartographY), OMI (Ozone Monitoring Instrument), GOME-2 (Global Ozone Monitoring Experiment-2) and TROPOMI (TROPOspheric Monitoring Instrument). In particular, the OMI sensor has a relatively high spatial resolution and long-term observations on NO2. Compared to NO2, the development of remote sensors on observing atmospheric NH3 has been more delayed. Presently, the atmospheric NH3 columns can be retrieved from TES (Tropospheric Emission Spectrometer), AIRS (Atmospheric Infrared Sounder), IASI (Infrared Atmospheric Sounding Interferometer) and CrIS (Cross-track Infrared Sounder)17.
The process of IN deposition includes dry and wet deposition. Atmospheric dry deposition refers to the process in which nitrogenous substances in the form of particulate matter and gases in the atmosphere are transported to the Earth’s surface by gravity, adsorption of particulate matter and direct reception by plant stomata in the absence of precipitation18. It is typically estimated using inferential model that take into account the near-surface concentration of nitrogenous substances and the deposition rate19. Wet deposition is the process by which soluble IN is adsorbed by water droplets aloft and then falls to the ground, mainly in the form of particulate matter, during precipitation events (rain, snow, fog, etc.).
In this study, yearly IN depositions across China were estimated based on the atmospheric nitrogenous substance concentrations from satellite observations. The models were initially constructed to estimate dry and wet IN deposition fluxes using remotely sensed NO2 and NH3 columns and an atmospheric CTM; then the estimation results on IN depositions were evaluated using the ground observations; and finally, the data of seven major components in the IN deposition fluxes during 2011- 2020 across China were provided.
Methods
Database structure
The atmospheric IN deposition fluxes database20 consists of three files (Fig. 1). The ‘data file’ provides yearly data for the dry, wet and total IN deposition fluxes. Specifically, dry deposition is the sum of two forms, gaseous and particulate, including NO2, HNO3, NH3, NO3− and NH4+.Wet deposition is the sum of both NO3−-N and NH4+-N. The ‘readme file’ describes the ‘data file’ and the units of all variables included. The ‘source file’ includes the full references used in the database, which comprises satellite data and precipitation data.
Data acquisition
The atmospheric nitrogen components are very complex, mainly including NH3, NO2, HNO3 gases, and particulate matter of NH4+ and NO3−. NO2 and NH3 are very critical precursors among the abundant IN components in the atmosphere. At present, the development of satellite technology has detected NO2 and NH3 concentrations in the atmosphere. These satellite observations could be used to estimate atmospheric IN deposition.
NO2 columns from OMI have been available since October, 2004. OMI is a UV-Visible wavelength spectrometer on the polar-orbiting NASA Aura satellite, launched on 15 July 2004, and follows a sun-synchronous orbit with an equator crossing time near 13:45, local time. In this study, the columnar NO2 is provided in the publicly released level 2.0 (http://www.temis.nl/), with an improved retrieval algorithm method (DOMINO 2.0) and the monthly tropospheric NO2 columns from Jan 2011 to Dec 2020 are used to estimate NO2 deposition fluxes, with a spatial resolution of 0.125° × 0.125°. Data quality control was used to select NO2 columns: (1) screen and exclude the image elements affected by OMI row anomalies; (2) select the image elements with less than 30% cloud inversion values to obtain as many valid image elements as possible.
We also used daily NH3 columns from the IASI during Jan. 2011 - Dec 2020 (http://cds-espri.ipsl.upmc.fr/etherTypo/index.php?id=1700&L=1). The data is in Network Common Data Form (NetCDF) format, with a unit of molec·cm−2 and a spatial resolution of 0.25° × 0.25°. The sensor provides global coverage twice a day, at 9:30 a.m. and 9:30 p.m. We used the daytime column, when there is a greater thermal contrast and greater sensitivity to atmospheric NH38. In terms of data quality control, we required a cloudiness of less than 25% and a relative error lower than 100% or absolute error less than 5 × 15 molec·cm−2.
We interpolated to estimate the missing values for the collected NO2 and NH3 columns, respectively. For the NO2 columns, we resampled them to match the same spatial resolution as NH3. For the NH3 columns, we first synthesized the daily data to calculate the arithmetic average of monthly and yearly columns17. To generate continuous maps, we performed the Original Kriging interpolation to estimate the values at these cells with outlier values.
GEOS-Chem is a three-dimensional (3-D) global chemical transport model that simulates the chemical and transport processes. The source program is available free of charge from the GEOS-Chem Chemistry Model Group at Harvard University (http://acmg.seas.harvard.edu). For the emission inventory, the anthropogenic sources of NOx and NH3 were obtained from the monthly MIX inventory (http://meicmodel.org/).
The observation data of gaseous, particulate, wet N depositions at sites in China were collected as validation data from the NNDMN7,21. We used the ground-level NH3 and NO2 concentrations from 32 sites in 2014 to evaluate the performance of dry N deposition model; In wet deposition model, we used the measured wet NH4+ and NO3− deposition from 32 sites during 2011–2012 to establish mixed-effects model22. In addition, the monthly precipitation data from 2011 to 2020 across China were provided by China Meteorological Administration (CMA). The detailed discussion on the data set and processing can be found at China Meteorological Data Sharing Service System (http://data.cma.cn/).
Dry deposition model
The dry deposition model is constructed using an inferential method, expressed as23:
Where C denotes satellite-derived surface NO2 and NH3 concentration and Vd indicates the rate of dry N deposition.
We used the stratified NO2 and NH3 concentrations simulated by GEOS-Chem to fit their contour functions in the vertical direction, which converts the column from satellite monitoring to those at surface level24. In this study, the 47 layers’ NO2 concentrations at 2° × 2.5° were used to construct the vertical profile models. Taking the approach to estimate surface NO2 concentrations as an example, steps are introduced in the following. The procedure to estimate the surface NH3 concentrations is similar to that.
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1)
Simulate NO2 concentrations in the atmosphere by GEOS-Chem. The hour NO2 concentrations at 47 vertical layer (from the Earth’s surface to the top of the stratosphere) at 00:00, 6:00, 12:00, 18:00 were simulated by GEOS-Chem and the daily NO2 concentrations at 12:00 were synthesized into monthly data.
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2)
Simulate the profile function to describe the vertical variations of NO2 concentrations. Since single Gaussian fitting may not capture the detail of vertical distribution of NO2 well25,26, we used multiple Gaussian functions to simulate the profile of the tropospheric NO2 concentrations27.
$$\rho \left(Z\right)={\sum }_{i=1}^{n}{{\rho }_{max,i}e}^{-{\left(\frac{z-{z}_{0,i}}{\sigma }\right)}^{2}}$$(2)Here, ρ(Z) represents the concentration of NO2 at a certain height level and Z is the height of a layer in the GEOS-Chem; n ranges from 2 to 6, representing the number of Gaussian items; ρmax,i, z0,i and σ are the maximum NO2 concentration, the corresponding height with the maximum NO2 concentration and the thickness of the NO2 concentration layer. The determination coefficient of R2 and root-mean-square error (RMSE) were used to assess each model performance. The mode with the highest R2 and lowest RMSE (i.e., determined the value of n) was selected to describe the profile function.
The NO2 columns in troposphere are simulated by integral calculation:
$$\varphi ({h}_{{\rm{trop}}})={\int }_{0}^{{h}_{{\rm{trop}}}}\rho (Z){\rm{d}}x$$(3)\(\varphi \left({h}_{{\rm{trop}}}\right)\) denotes NO2 columns and htrop indicates the tropospheric height.
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3)
Estimate the surface NO2 concentration based on the proportional of the near-surface to tropospheric concentrations obtained from both model simulations and satellite estimates.
$${S}_{{\rm{G}}\_{{\rm{NO}}}_{2}}={S}_{{\rm{trop}}}\times \frac{\rho \left({h}_{{\rm{G}}}\right)}{\varphi \left({h}_{{\rm{trop}}}\right)}$$(4)Where SG_NO2 and Strop represent the surface NO2 concentration and the tropospheric column from satellite; and ρ(hG) and \(\varphi \left({h}_{{\rm{trop}}}\right)\) represent the model-simulated NO2 concentration at surface level and tropospheric NO2 column, respectively.
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4)
Convert the instantaneous satellite-derived surface NO2 concentration to the daily average using the ratio of average surface NO2 concentration to that at satellite overpass time by GEOS-Chem.
Where \({S}_{{\rm{G}} \mbox{-} {{\rm{NO}}}_{2}^{* }}\) and \({S}_{{\rm{G}} \mbox{-} {{\rm{NO}}}_{2}}\) are near-surface NO2 concentration of daily average and that at satellite overpass time. \({G}_{{\rm{GEOS}} \mbox{-} {\rm{Chem}}}^{1-24}\) and \({G}_{{\rm{GEOS}} \mbox{-} {\rm{Chem}}}^{{\rm{overpass}}}\) are NO2 concentrations simulated by GEOS-Chem of daily average and that at satellite overpass time, respectively. Here we use the daily NO2 concentrations at 12:00 to replace the overpass time concentrations.
However, the satellite products cannot obtain the atmospheric gaseous HNO3, and particulate NO3− and NH4+. Based on ground measurements or the simulation results on NO2, HNO3, NO3−, NH3 and NH4+, the linear relationships were constructed between NO2, gaseous HNO3 and particulate NO3−, and between NH3 and NH4+, on monthly and annual scales6,19,28. Using these linear relationships and the remotely sensed estimation on surface NO2 concentrations, the monthly averages of the surface concentrations of NO3− and HNO3 can be deduced. In this study, we used the surface IN concentration relationships simulated by GEOS-Chem and the satellite-estimated surface NH3 and NO2 concentrations to derive the surface gaseous HNO3, particulate NO3− and NH4+ concentrations24,28.
To determine the Vd in the inferential model, a Big-leaf model was used to simulate the deposition rates of the major N fractions. It can be expressed as29:
where ra is the aerodynamic resistance, rb is the quasi-laminar boundary sub-layer resistance, rc is the canopy resistance and Vg is the gravitational settling velocity.
For gases, the gravitational settling velocity can be ignored. The measurement of canopy resistance is the most complex, and the basic starting point is to generalize the crop canopy as a “big leaf”, which is expressed as the combined stomatal resistance and soil resistance of each leaf according to the “big leaf theory”30. In this study, an inferential model was used to quantify dry deposition as two components: surface nitrogen fraction concentration and deposition rate.
Wet deposition model
The conventional “bottom-up” method to estimate IN wet deposition by CTM contains clear in-cloud, sub-cloud and precipitation processes, which relies on the emission inventory and accuracy of pattern reflection and transmission. In this study, a top-down estimation method based on satellite data was used by constructing a wet deposition model (mixed-effects model) with mixed-layer NO2 and NH3 concentrations, nitrate and ammonia wet deposition from sites observations and precipitation data. This method has two key steps below:
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1).
Convert the N concentrations from troposphere to atmospheric boundary layer
The clear process of IN wet deposition usually starts at the rainfall height rather than the top troposphere height. It is more reasonable that the NO2 and NH3 concentrations below the rainfall height should be used to build the wet deposition model6,31. As rainfall heights could not be performed and nitrogen components were mainly within the atmospheric boundary layer (ABL), the N concentrations in the atmospheric boundary layer heights were used here instead32. The main conversion is expressed as:
$${S}_{ABL}={S}_{{\rm{trop}}}\times \frac{\varphi ({h}_{ABL})}{\varphi ({h}_{{\rm{trop}}})}$$(7)$$\varphi ({h}_{{\rm{ABL}}})={\int }_{0}^{{h}_{{\rm{ABL}}}}\rho (Z){\rm{d}}x$$(8)Where SABL is the ABL NO2 or NH3 columns, and Strop is the tropospheric NO2 or NH3 columns from satellite. \(\frac{\varphi \left({h}_{ABL}\right)}{\varphi \left({h}_{{\rm{trop}}}\right)}\) is the ratio of the model-simulated ABL NO2 or NH3 column to its tropospheric column concentration, where \(\varphi \left({h}_{{\rm{ABL}}}\right)\) can be obtained from the integration of the profile function from 0 to the top of the atmospheric boundary layer (hABL).
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2).
Develop a linear mixed-effects model monthly scale,using ABL NO2 and NH3 columns from satellite, precipitation data, and sites observations on IN wet deposition (NO3–-N and NH4+-N)33.The model combines fixed effects, which generally refer to the response variable (dependent variable); and random effects, which refer to the relevant influencing factor variables. In this study, the model to estimate wet deposition of nitrate or ammonia N was followed34:
Where Nij is wet NO3− or NH4+ deposition at month i and site j; Pij is precipitation and (SABL)ij means the mixed layer NO2 or NH3 column concentration at station j in month i. Pij×(SABL)ij represents an indicator of the combined effect of atmospheric precipitation and inorganic nitrate-N or ammonia-N compounds. βi and αj are the slope and intercept of random effects, representing seasonal variability and spatial effects. εij represents the random error at month i and site j.
Data Records
The atmospheric inorganic nitrogen deposition fluxes in China database from 2001 to 2020 is available at https://doi.org/10.6084/m9.figshare.24057120.v320. The database consists three files: the ‘data file’ is the main file, includes deposition fluxes of dry, wet and total IN. The ‘readme file’ and the ‘source file’ explains the description, units, and the full references used in the database.
Technical Validation
In terms of the temporal trend, there is a small increase in the total IN deposition over land in China during 2011–2020 (Fig. 2a). The dry deposition fluxes had a weak upward trend over the ten-year period, but the fluctuation was small. The wet deposition fluxes fluctuated up and down between years due to the influence of rainfall35,36, but showed a clear decreasing trend in the latter five years. This trend, transitioning from growth to stabilization to decline, reflected the role and process of policy control and emission reduction measures. In order to more accurately investigate the temporal trends in N deposition fluxes, we should remove the influence of the rainfall amount37. In this work, the ratio of the wet N deposition fluxes and precipitation, namely concentration of dissolved inorganic nitrogen (DIN) in precipitation, was selected as an indicator to reflect the temporal variability of the N deposition fluxes after removing the effect of the rainfall amount (Fig. 2b). The wet N deposition fluxes displayed decreased temporal trend during 2011−2020, which was consistent with the trend presented by the NNDMN sites9. In the previous study, ammonia-N showed an increasing trend and nitrate-N showed a decreasing trend from 2008 to 2017, and the ratio of reduced to oxidized N deposition in China increased since 201122. Even though nitrate-N decreased significantly from year to year due to the strict control of nitrogen oxides in the 12th Five-Year Plan38, the trend of total N still showed a certain increase, which was also confirmed in this study.
Quantitatively, the annual averages of total IN deposition in China ranged from 16 to 22 kg N ha−1. The ranges of annual averages of dry deposition was 7–10 kg N ha−1 and the wet deposition was 9–12 kg N ha−1. The proportion of wet deposition accounted for a higher percentage of total deposition than dry deposition in China. However, the contribution from dry deposition gradually increased over time. These results demonstrated the critical role of dry deposition in estimating total IN deposition8.
The spatial distributions of dry, wet, and total N deposition fluxes are described in Fig. 3. For dry deposition, Eastern China (including Shandong, Hebei, Henan, Jiangsu, Beijing, Tianjin, Xi’an, Taiyuan, Chengdu, Chongqing, etc.) had the highest values of dry deposition, followed by the regions in eastern and southeast China, central Liaoning, and northwest China. Low values were mainly distributed in western China (Tibet, Qinghai), northwest China (southeast Xinjiang, northwestern Inner Mongolia), etc. The high values of wet deposition were mainly concentrated in Jiangsu, Anhui, and eastern Hubei provinces, as well as Chengdu and Chongqing in Sichuan Province, Hebei, Henan, and western Guangdong Province, and Beijing. The low values were mainly concentrated in western China (Xinjiang, Tibet, Qinghai, northwestern Inner Mongolia, etc.) and were in high agreement with the spatial variations of precipitation. There were large differences in dry and wet deposition ratios in different regions, with Sichuan, Chongqing, and Guangdong mainly attributed to wet deposition because of higher precipitation in southern regions compared to northern regions of China. Overall, the spatial heterogeneity of atmospheric IN deposition is large, mainly characterized by lower values in the western region and higher values in the eastern region.
In our previous studies26, the accuracy of the simulated profiles of NH3 and NO2 concentrations by Gaussian functions had been evaluated, with the R2 above 0.95 for more than 99% of the grid points. Based on the concentrations collected from observation sites, the point-to-point validation on the remotely sensed estimates of near-surface NH3 and NO2 concentrations was performed with R2 of 0.72 and 0.71, respectively. Furthermore, the regression correlation coefficients for the wet deposition NH4+ and NO3- mixed effects models reached to 0.81 and 0.87, respectively6,22,24,27.
In addition, the estimates of atmospheric IN deposition fluxes were within a reasonable range compared to previous studies8,10. The high IN deposition region of the North China Plain shown in this study has been consistently found in studies by other scholars7,35,39. The percentage of dry deposition gradually increased during 2011–2020, which was consistent with the results from the previous studies8,40.
Code availability
The inorganic nitrogen deposition database1.0 describes the data is available at Figshare data record (https://doi.org/10.6084/m9.figshare.24057120.v3)20.
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Acknowledgements
This work was supported by the National Natural Science Foundation of China (42371378), the Basic Research Program of Jiangsu Province (NO.: BK20211156) and National Natural Science Foundation of China (NO. 41471343). We acknowledge the free use of IASI NH3 and OMI NO2 column, CMA meteorological data, as well as GEOS-Chem model.
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Qian Gao and Xiuying Zhang wrote the paper; Xiuying Zhang, Lei Liu, Xuehe Lu and Yingying Wang compiled the data and designed the database. All co-authors reviewed and commented on the manuscript.
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Gao, Q., Zhang, X., Liu, L. et al. A database of atmospheric inorganic nitrogen deposition fluxes in China from satellite monitoring. Sci Data 10, 698 (2023). https://doi.org/10.1038/s41597-023-02607-z
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DOI: https://doi.org/10.1038/s41597-023-02607-z
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