Next Article in Journal
3D Visualization of Bamboo Node’s Vascular Bundle
Next Article in Special Issue
Assessment of NO2 Purification by Urban Forests Based on the i-Tree Eco Model: Case Study in Beijing, China
Previous Article in Journal
Effects of Urbanization on the Dynamics and Equity of Access to Urban Parks from 2000 to 2015 in Beijing, China
Previous Article in Special Issue
Influence of Simulated Nitrogen Deposition on the Soil Seed Bank of a Subtropical Evergreen Broadleaved Forest
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Forests
Volume 12
Issue 12
10.3390/f12121798
forests-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Soil Nitrogen and Sulfur Leaching in a Subtropical Forest at a Transition State under Decreasing Atmospheric Deposition

by
Piaopiao Ke
1,
Gaoyue Si
2,
Yao Luo
1,
Zhenglin Cheng
1,
Qian Yu
1,* and
Lei Duan
1
1
State Key Laboratory of Environmental Simulation and Pollution Control, School of Environment, Tsinghua University, Beijing 100084, China
2
School of Agriculture and Biology, Shanghai Jiaotong University, Shanghai 200240, China
*
Author to whom correspondence should be addressed.
Forests 2021, 12(12), 1798; https://0-doi-org.brum.beds.ac.uk/10.3390/f12121798
Submission received: 20 October 2021 / Revised: 10 December 2021 / Accepted: 16 December 2021 / Published: 17 December 2021
(This article belongs to the Special Issue Biogeochemical Cycles of Nitrogen in Forest Ecosystems)
Browse Figures
Versions Notes

Abstract

:
Anthropogenic emissions of nitrogen- (N) and sulfur (S)-containing pollutants have declined across China in recent years. However, the responses of N and S depositions and dynamics in soil remain unclear in subtropical forests. In this study, the wet and throughfall depositions of dissolved inorganic N (DIN) and SO42− were continuously monitored in a mildly polluted subtropical forest in Southeast China in 2017 and 2018. Moreover, these solutes in soil water along the soil profile were monitored in 2018. Throughfall deposition of DIN and S decreased by 59% and 53% in recent 3 years, respectively, which can be majorly attributed to the decreases in wet depositions of NO3 and SO42−. Meanwhile, NH4+ deposition remained relatively stable at this site. Even though N deposition in 2018 was below the N saturation threshold for subtropical forests, significant N leaching still occurred. Excess export of N occurred in the upper soil layer (0–15 cm), reaching 6.86 ± 1.54 kg N/ha/yr, while the deeper soil (15–30 cm) was net sink of N as 8.29 ± 1.71 kg N/ha/yr. Similarly, S was excessively exported from the upper soil with net flux of 14.7 ± 3.15 kg S/ha/yr, while up to 6.37 ± 3.18 kg S/ha/yr of S was retained in the deeper soil. The significant N and S leaching under declined depositions suggested that this site possibly underwent a transition state, recovering from historically high acid deposition. Furthermore, the rainfall intensity remarkably regulated leaching and retention of SO42− and DIN at this site. The impacts of climate changes on N and S dynamics require further long-term monitoring in subtropical forests.

1. Introduction

Elevated nitrogen (N) and sulfur (S) depositions have been widely reported to cause acidification and eutrophication in terrestrial ecosystems, influencing nutrient balance, vegetation growth, and biodiversity in Europe [1,2] and North America [3] in 1970s, and in East Asia in around a decade later [4]. Nitrogen deposition could act as an external N supply and improve ecosystem productivity if total biotic N demands in the ecosystems are not exceeded. However, excel N input would lead N saturation, indicated by significant N leaching from soil [5]. Enhanced atmospheric S and N depositions resulted primarily from increased anthropogenic emissions of sulfur dioxides (SO2), nitrogen oxides (NOx), and ammonia (NH3) [4]. Following dramatic economic development since the 1970s, the anthropogenic emissions of these air pollutants rapidly increased in China [4]. The concomitant high loads of N and S to forests have caused significant soil acidification, especially in South China, where the forest soils are susceptible to acid deposition [6,7].
Due to successful implementations of pollution control policies in China, SO2 and NOx emissions have significantly declined since 2006 and 2011, respectively [8,9], while total NH3 emissions have remained relatively stable [9]. It has been suggested that N and S depositions generally decreased across China in recent years [6,8,10,11]. However, the actual status of N and S depositions and responses of subtropical forest soils are not completely understood. To date, long-term field investigations of N and S depositions in subtropical forests are scarce, and even fewer studies have monitored N and S dynamics in soil, as most studies have focused on the impacts of N addition in forest ecosystems [12,13]. Generally, NO3 concentration in soil water and N leaching respond more rapidly than soil organic matter and wood to changes in atmospheric N deposition [13,14,15]. A sharp decline in N deposition has led to an instantaneous reduction in N leaching and soil mineralization and immobilization rates in a heavily N-polluted subtropical forest in Southwest China [13,16]. Nevertheless, changes in N leaching from soil at this site did not follow the hysteretic model proposed to predict the responses of temperate forests to declined N deposition [15]. The SO42− leaching decreased concomitantly with S deposition (180 kg S/ha/yr) and net accumulation of SO42− in soil continued to occur in this forest [8,17]. In contrast, long-term monitoring in Europe and North America indicated excess S export from temperate forest soils under low atmospheric SO42− deposition (<16 kg S/ha/yr) [1,2,18], which can possibly be attributed to the historic accumulation of S in soil, e.g., the desorption of SO42− and mineralization of organic S [19]. Net release of SO42− may delay the recovery of forest ecosystems from acidification if it is caused by the legacy effects of historic S deposition [1,2,4,18,20]. Regarding the spatial variation of atmospheric N and S depositions [13,21], more field investigations in subtropical forests are required to understand the status of N and S depositions and the corresponding responses of subtropical forest soil.
So far, the responses of subtropical forests to declined N and S depositions in China have only been investigated in a forest that still receives high inputs of N and S. How less polluted subtropical forests in China respond to the declined depositions remains unknown, to our knowledge. In this study, a mildly polluted subtropical forest in Southeast China was revisited in 2017 and 2018 and temporal characteristics of the dissolved inorganic nitrogen (DIN, represented as sum of NO3 and NH4+) and SO42− depositions via precipitation and throughfall were investigated. In addition, the dynamics of NO3, NH4+, and SO42− in soil water along the soil profile were monitored in 2018. The N and S budgets in the surface soil (0–30 cm), where most interactions between vegetation, soil, and microbes occurred, were established and compared with previous monitoring [22] to demonstrate the responses of this forest to the decreased depositions.

2. Materials and Methods

2.1. Site Description

The field investigation in this study was carried out in Qianyanzhou Ecological Station (QYZ, 115°4′ E, 26°45′ N, managed by the Chinese Academy of Sciences) from February 2017 to April 2019. This site is located in Jiangxi Province and is under a subtropical monsoon climate, with major rainfall events appearing between March and September [23]. The mean annual precipitation and temperature are 1494 mm and 19.2 °C [24], respectively. Furthermore, this site is approximately 42 km southeast of the nearest city, Ji’an City, and there are no significant industrial plants or coal burning boilers within ~30 km [25]. The predominant wind direction is southeast in the summer and northwest in the winter [26]. The forest is Pinus massoniana predominated, with approximately 17 ha in area, and surrounded by agricultural fields [26]. The stand age of the pine trees is around 35 years and the canopy height is about 16 m [27]. The major soil type is red earth, highly weathered from red sand rock, and the soil pH is 4.6 [28]. The fine roots are concentrated at 0–20 cm depth, with approximately 63% at 0–10 cm depth [29,30]. This site received 19.9 kg N/ha/yr and 27.8 kg S/ha/yr in precipitations in 2014 [9], which were both at lower levels of corresponding depositions across subtropical forests in China, ranging 18.2–88.2 kg N/ha/yr and 4.8–144 kg S/ha/yr for N and S, respectively [10,31,32]. Hence, this site could be considered as a mildly polluted site in South China [25].

2.2. Sampling and Chemical Analysis

A total of three 10 m × 10 m plots were randomly set up under the forest canopy, with two throughfall collectors (at the nonadjacent corners) and two sets of soil water lysimeters near the center in each plot. The throughfall collector consisted of an 8.6 cm diameter funnel, covered with nylon gauze to prevent entrances of litterfall and insects, and an opaque 3 L bottle to store water [25]. Another six sets of collectors were installed in open areas for bulk precipitation sampling. Soil water samples at 5 cm depth (S5, topsoil), 15 cm depth (S15, in the root zone), and 30 cm depth (S30, below the root zone) were collected through Rhizon lysimeters (Eijkelkamp, Wageningen, The Netherlands). The bulk precipitation, throughfall, and soil water were sampled weekly and then quickly stored at 4 °C in a refrigerator. The weekly samples in the month were lumped together for subsequent chemical analysis. All the monthly mixed water samples were filtered through 0.45 µm syringe filters and then analyzed for cation and anion concentrations by ion chromatography (ICS-2000, Dionex Corp., Sunnyvale, CA, USA). Detailed sampling and chemical analysis method can be seen in Refs. [16,17,33]. Since humus layer accumulates on the topsoil, solute fluxes in soil water at S5 were considered as total fluxes from the organic layer and topsoil.

2.3. Data Processing

Monthly fluxes in precipitation, throughfall, and soil water along the soil profile were calculated as ion concentration multiplied by the corresponding water fluxes. Mean values of the three plots were applied to represent the monthly depositions and solute fluxes in the soil water at this site. For soil solution, where direct measurements of the water fluxes do not exist [21], the water fluxes were estimated based on Na+ balance according to the conservativeness of Na+ in soil water [17]. However, the mineral weathering and potential cation exchange might induce uncertainties to the estimation of soil water fluxes, particularly in deeper soil [8]. In this study, the flux of soil water at S30 was approximated as stream water flux in this region [21,22], as the evapotranspiration below the root zone could possibly be minor. The seasonal correlations between stream water fluxes and precipitations was applied based on hydrological researches in this region [22,34]. Since the stream water flux was not measured in this study, there was inevitable uncertainty of the soil water flux calculation at S30. However, the seasonal pattern of rainfall in the previous monitoring was similar to that this study [34] and the correlations may still be applicable to this study. The accumulative fluxes in the seasons and years were attained by directly adding up monthly fluxes, while seasonal and annual concentrations were volume-weighted averages. Detailed formulation could be seen in Ref. [25]. The enhanced deposition from precipitation to throughfall was attributed to dry deposition, while the decreased concentrations and deposition were likely due to the overriding process of canopy interception [26,35,36]. During the transformation between NH4+ and NO3 in soil, H+ could be generated (H+prod, N) and induce soil acidification [17,37], as follows:
H+prod, N = (NH4+i − NH4+o) + (NO3o − NO3i)
where NH4+i and NO3i are input fluxes of NH4+ and NO3, respectively, and NH4+o and NO3o are the leaching fluxes of NH4+ and NO3, respectively.
Due to sampling problems, the soil water collections stopped from August 2017 to March 2018. Hence, only data of depositions and soil solution fluxes in 2018 were discussed in detail in this study. Results in 2017 can be seen in Figure A1 and Figure A2. All the graph drawing and the correlation analysis were conducted in OriginPro 2021.

3. Results and Discussion

3.1. Seasonal DIN and S Concentrations and Fluxes

The annual water flux of throughfall in 2018 was 1097 mm, 3.8% smaller than the precipitation (Figure 1), while the annual soil water flux below the root zone accounted for 57.0% of the throughfall. Annual mean concentrations of SO42−, NH4+, and NO3 in precipitations were 2.84 ± 0.67, 0.833 ± 0.056, and 1.31 ± 0.11 mg/L, respectively. Generally, higher ion concentrations were observed in throughfall than those in precipitations in each season, except in the spring, when NH4+ concentration in throughfall decreased by 3% from precipitation. Highest concentrations of SO42−, NO3, and NH4+ in precipitation and throughfall were mostly observed in the autumn or winter, when the water fluxes were smallest (Figure 1 and Figure A1). The ratio between NH4+ and NO3 concentrations decreased from bulk precipitation (1.86–2.49) to throughfall (1.37–2.48), except in the summer. The seasonal variation of N concentration in precipitation was similar to the observation at this site during 2014 and 2015 [22,25]. From throughfall to soil water within depth of 15 cm, SO42− and NO3 concentrations increased gradually (Figure 1). From 15 cm to 30 cm, however, the concentrations decreased, except in the autumn. Generally, the concentrations of SO42−, NH4+, and NO3 in the precipitation, throughfall, and soil water were negatively correlated with the corresponding water fluxes (p < 0.1). For NH4+, the concentration decreased sharply from throughfall to soil waters. The ratio between NH4+ and NO3 concentrations ranged from 0.06 to 0.55 in these three layers of soil.
The annual fluxes of SO42− and DIN via precipitation in 2018 were 10.8 ± 0.6 kg S/ha/yr and 10.8 ± 0.22 kg N/ha/yr, respectively. The highest SO42− flux in throughfall occurred in the spring, while the maximum throughfall deposition of DIN occurred in the summer (Figure 1). Dry deposition of S and oxidized N peaked in the spring, while the highest dry deposition of reduced N appeared in the summer. Meanwhile, significant canopy interception of NH4+ occurred in the spring (in 2017) and summer (in 2018), accounting for 19% and 7% of the wet deposition, respectively (Figure 1). For NO3, the significant canopy interception appeared in the autumn of 2017, accounting for 11% of the wet deposition (Figure A2). The observed interception rate of NO3 in the autumn was comparable to that previously reported for Pinus massoniana-predominated forests in this region in the winter [36]. Wet surface of the forest canopy and vegetation demands of N could facilitate canopy interceptions of nutrients [35,36]. In other seasons, dry deposition of N might override the canopy N interception, leading to increased concentrations and depositions from precipitation to throughfall.
The annual leaching of SO42− and DIN (majorly NO3 in soil waters) from the root zone reached 24.3 ± 0.94 kg S/ha/yr and 12.6 ± 0.092 kg N/ha/yr, respectively. In each season, the NH4+ flux decreased sharply from throughfall to the S5 layer, and further decreased gradually along the soil profile. Although the DIN flux in the S30 layer was smaller than the throughfall deposition, the S5 and S15 layers had relatively larger fluxes than the throughfall deposition. The SO42− flux from the root zone was larger than the throughfall deposition, except in the autumn. Notably, SO42− and DIN leaching in the S30 layer were always smaller than the leaching in the upper layer. Moreover, the leaching of SO42− from the soil significantly increased at 5–15 cm depth in the spring and summer, on the contrary to the autumn and winter (Figure 1).

3.2. Decreasing Trend of Atmospheric DIN and S Depositions

From 2014–2015 to 2017–2018, the annual mean concentrations of SO42− and DIN in precipitation decreased by 48% and 30%, respectively. Meanwhile, the wet deposition of SO42− and DIN decreased by 63% and 55%, respectively (Figure 2). The wet depositions of SO42− and DIN were relatively higher in 2018 than those in 2017, even with smaller anthropogenic emissions. This was possibly due to significantly less precipitation in 2017 (1467 mm, 978 mm, and 1133 mm precipitation in 2014, 2017, and 2018, respectively). Compared with results in 2014 [25], with exactly the same sampling protocol and places, the throughfall deposition of SO42−, NO3, and NH4+ in 2017–2018 decreased by 59%, 69%, and 31%, respectively. In addition, during 2017–2018, total emissions of SO2, NOx, and NH3 in Jiangxi Province decreased by 53%, 11%, and 17%, respectively, from 2014–2015 (Figure 2). The declining trend of S deposition was accordant with other field investigations across forests in China [4,8], following the rigorous air pollution control and adjustment of energy production structures in China [8,9,10]. In the case of N, wet deposition of NO3 responded quickly to the regional emission reduction, while wet deposition of NH4+ remained relatively stable, fluctuating in a range of 6.25–7.38 kg N/ha /yr, possibly due to nearby agricultural fields. Similar temporal patterns of NO3 and NH4+ in precipitations at this site have also been observed at other background sites (forest, coastal, and grassland [38]) across China, where significantly decreased NO3 deposition and relatively stable NH4+ deposition [10] were monitored from 2011 to 2018. Furthermore, SO2, NOx, and NH3 emissions have been anticipated to continue decreasing across China [39], implying further declines of S and N deposition nationwide. Nevertheless, NH4+ deposition via precipitations at this site could possibly remain stable due to uncontrolled NH3 emissions from nearby agricultural activities. Furthermore, S and N depositions in 2017–2018 in this forest were both at lower levels of corresponding depositions across forests in South China [10,31,32,33], but these were higher than those recently observed in most temperate and boreal forests across Europe—0.576–13.6 kg S/ha/yr and 1.27–19.2 kg N/ha/yr [1,3,40]—and in North America—2.00–23.0 kg S/ha/yr and 1.15–11.0 kg N/ha/yr [15,18,20,41]. The relatively high levels of S and N deposition in this and other forests in South China emphasized the impacts of widespread anthropogenic emissions of SO2 and reactive nitrogen across subtropical zones [10].
Additionally, the regionally declined anthropogenic emissions seemed to have little influence on the dry deposition of SO2 (or H2SO4 in the fog [21]) and NOx (or nitric acid and particulate nitrate [10]) at this site. Contrastively, dry deposition of NH3 (or particulate ammonium [10]) largely decreased. The regional distribution of industrial plants and various canopy interception (Section 3.1) of solutes could induce the different responses of dry deposition of S, oxidized N, and reduced N to regional emission reductions. According to previous monitoring and estimation nationwide in China [10,11], contributions of N dry deposition are generally increasing since 2011. At this forested site, the importance of S and N dry depositions increased in recent years, following decreases in corresponding wet depositions. Moreover, during 2014–2015, the oxidized N deposition overrode the reduced N deposition, which shifted to the contrary in 2017–2018. Agricultural activities nearby might become the main sources of N deposition at this site in the future.

3.3. Net N Retention and Excess S Export in Soil under Declining Depositions

Excess N export was observed in the upper soil (0–15 cm depth), while net N retention was observed in the deeper soil (15–30 cm). The N leaching from the root zone accounted for 75% of the total deposition (Figure 2 and Table 1). According to previous investigations in South China, N saturation threshold in acidic subtropical forest soils was estimated as 26 kg N/ha/yr [33]. In 2014–2015, total DIN deposition at this site was larger than 28 kg N/ha/yr, and the leaching constituted 23% of throughfall deposition ~40 cm below soil [22]. Even though the DIN deposition at this site in 2017–2018 was smaller than the saturation threshold [33], significant DIN leaching still occurred and accounted for a larger proportion of the throughfall input than that during 2014–2015. A higher ratio of N leaching to N deposition has also been monitored in a subtropical forest in Southwest China [13] and some temperate forests [14,45] under declined deposition. Considering the enhanced N leaching under declined deposition, this site was likely undergoing a “transition” state and required longer time to approach a “new” steady sate [2].
The net N retention and leaching are affected by many factors, as NO3 and NH4+ could experience complexed transformation processes apart from deposition and leaching in soil [46,47,48]. Since roots of Pinus massoniana prefer NO3 rather than NH4+ [13,33], NH4+ immobilization by microbes and autotrophic nitrification are considered as major pathways of NH4+ consumption. Meanwhile, NH4+ in soil could be produced from mineralization and dissimilatory reduction of nitrate to ammonium (DNRA) [13,48]. According to the 15N tracing experiment of forest soil in this region, the potential of autotrophic nitrification and DNRA was low, possibly due to the low soil pH [48], which has also been observed in other subtropical forests [13,49,50]. Hence, the largely declined NH4+ fluxes in soil water were more likely due to the predominance of NH4+ immobilization, which then accumulated in the organic matters. In the case of NO3, nitrification (including autotrophic nitrification and heterotrophic nitrification) is considered as another important source of NO3 in soil, aside from atmospheric deposition. Meanwhile, vegetation uptake, immobilization, denitrification, and DNRA are major pathways for NO3 consumption [48]. As described above, the distinctly increased NO3 fluxes in soil water from throughfall deposition implied the dominance of heterotrophic nitrification and mineralization processes over the NO3 consumption. Additionally, mineralization of litterfall could also increase NO3 leaching in the organic layer, suggested by the rapid internal N cycle in subtropical forests [8]. Moreover, heterotrophic nitrification and N mineralization rate in subtropical forest soils possibly had a delayed recovery to the declined deposition [13], which eventually led to the increased ratio of N leaching to N deposition. In addition, NO3 flux at S30 significantly declined, compared with that at S15. Since the roots were concentrated at 0–20 cm depth [30], the vegetation uptake was unlikely to have induced the declined leaching. In contrast, denitrification process in soil could possibly take an important role in N mass balance [22]. The increasing humidity of soil and relatively stable soil temperature until 50 cm depth at this site [51] all benefitted the denitrification process in deeper soil.
In the case of SO42−, excess S tended to be exported from soil (Table 1), which has been widely reported across forests in Europe [1,2] and North America [18,20] during the recovery from historically high S deposition. Mineralization of organic S, desorption of previous adsorbed SO42− and bedrock weathering could all possibly contribute to the significant S export [1,2,18,20,52,53]. As the red earth at this site is highly weathered [17,54], weathering in the surface soil could be minor. Concomitant with high S deposition across South China [6,8,32], plenty S was stored in soil in forms of adsorbed SO42−, organic S, and/or reduced S [55], ranging 10.4–50.0 kg S/ha/yr [21,56]. The adsorption–desorption of SO42− follows the Freundlich equation, and absorbed SO42− on soil minerals could be released to soil solution again [57] under conditions of decreasing SO42− concentrations in soil solution and increasing soil pH. Additionally, in the topsoil and humous layer, the organic S predominated among adsorbed SO42− and other S species [54,56,58,59,60], and might participate in secondary production of SO42− [58,61,62]. The excess SO42− export in this forest possibly resulted from legacy effects of historic S deposition, e.g., desorption of previously adsorbed SO42− [8] and mineralization of accumulated organic S [52,58]. In a subtropical forest in Southwest China, the SO42− leaching decreased concomitantly with the SO42− deposition (180 kg S/ha/yr) but S remained to be accumulated in soil [8]. Contrastively, this site received much smaller S deposition, and excess SO42− was exported from the soil. The different status of S export between the two subtropical sites might result from different capacity of SO42− adsorption in soils [63] and SO42− concentrations in the throughfall [57]. Along the soil profile, excess export of S mainly appeared at S5 and S15, while significant retention process occurred at S30 (Table 1). The immobilization of SO42− by microbes, SO42− re-adsorption, and SO42− reduction could induce S retention or removal [52,53,64] in the deeper soil. Determination of relative importance of these biogeochemistry processes requires further investigation. Moreover, regarding the declining trend of S emissions and deposition across South China [9,32], inherent sources of SO42− from soils might become more and more important for subtropical forests [3,18].
Notably, the excess exports of N and S were larger in the spring and summer, when the water fluxes were abundant. The positive correlation between excess export of S (or N) and the water flux (Table 1, p < 0.05) was commonly observed in various forests [1,2,17,18] and meadow ecosystems [3]. Increased rainfall intensity could enhance the mineralization process together with SO42− desorption [3,18], leading to increased N and S leaching. During the recovery from acidification in a forested catchment in Japan, the forest soil was prone to retain SO42− under elevated air temperature and rainfall intensity due to prolonged growth season [3]. In this study, vegetation uptake and immobilization seemed to play a minor role in controlling SO42− budget in surface soil, but the climate conditions, e.g., rainfall intensity, tended to predominate in regulating SO42− leaching and retention. Additionally, the excess S leaching due to previously adsorbed S and/or accumulated organic S from soil is often accompanied with enhanced leaching of Al3+ and base cations, which delays the recovery of forest soil and surface water from acidification [18]. Furthermore, during the transformation between NH4+ and NO3, protons could be generated, preventing the increase in soil water pH [17]. Significant acidification occurred at the topsoil and root zones (when intensive precipitations appeared), with 38% of generated H+ being neutralized below the root zone (Table 1). Predictably, the significant leaching of DIN and SO42− could possibly continue for a long time in subtropical forests even under decreasing depositions in the future, resulting in persistent risks in acidification and eutrophication of terrestrial and aquatic ecosystems.

4. Conclusions

In this study, the wet and throughfall deposition and the solute fluxes along the soil profile were consecutively monitored in a mildly polluted subtropical forest in Southeast China in 2017–2018. From 2014–2015 to 2017–2018, the total deposition of SO42−, NO3, and NH4+ decreased by 59%, 69%, and 31%, respectively, while the dry deposition of S and oxidized N remained relatively stable at this site. In addition, the NH4+ deposition was shifted to dominate DIN deposition in 2017–2018. Deposition of S and NO3 could possibly continue decreasing while NH4+ deposition tended to remain stable at this site. Even though DIN deposition at this site decreased below the N saturation threshold, approximately 75% of deposited DIN still leached from the root zone. The significant leaching of DIN under declined atmospheric deposition possibly resulted from the delayed responses of mineralization and nitrification rates in subtropical forest soils to declined N deposition. Net S export from soil was observed at this site, amounting to 8.32 ± 0.48 kg S/ha/yr, which might result from the legacy effects of historically high S deposition. This site was likely undergoing a “transition” state and required longer time to approach a “new” steady sate. The continuous leaching of N and S could possibly delay the recovery of soil and surface water from acidification. Furthermore, the rainfall intensity remarkably regulated leaching and retention of SO42− and DIN at this site. The climate changes, e.g., higher temperature and more intensified rainfalls, could influence the S and N cycles in forest ecosystems. Hence, even though declined N and S depositions have been anticipated across China, the impacts of climate change, excess S export, and continuous DIN leaching to the forest ecosystem health and acidification recovery require further long-term monitoring in subtropical forests.

Author Contributions

Conceptualization, P.K. and Q.Y.; investigation, P.K., G.S., Y.L. and Z.C.; visualization, P.K. and Q.Y.; writing—original draft preparation, P.K.; methodology, G.S., Y.L. and Z.C.; writing—review and editing, Q.Y. and L.D.; funding acquisition, Q.Y. and L.D.; supervision, L.D.; project administration, L.D. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the National Natural Science Foundation of China, grant number 41877329 and 21607019, the special fund of State Key Joint Laboratory of Environment Simulation and Pollution Control, grant number 19L02ESPC, and China Postdoctoral Science Foundation, grant number 2020M670353.

Data Availability Statement

Data is contained within the article.

Acknowledgments

The authors greatly acknowledge the support from Qianyanzhou Forest Experimental Station and the help received in system maintenance and laboratory measurement from Yuanfen Huang and Jiawei Zhang and language editing from Loreena K. Avery and Harold W. Avery.

Conflicts of Interest

The authors declare no conflict of interest.

Appendix A

Forests 12 01798 g0a1 550
Figure A1. Seasonal water flux and ion concentrations of wet deposition (WD) and throughfall deposition (TF) in 2017. Bars filled with vertical lines, bars filled with bias, and bars without filling indicate SO42−, NH4+, and NO3, respectively.
Figure A1. Seasonal water flux and ion concentrations of wet deposition (WD) and throughfall deposition (TF) in 2017. Bars filled with vertical lines, bars filled with bias, and bars without filling indicate SO42−, NH4+, and NO3, respectively.
Forests 12 01798 g0a1
Forests 12 01798 g0a2 550
Figure A2. Seasonal flux of wet deposition (WD) and throughfall deposition (TF) in 2017. Bars filled with vertical lines, bars filled with bias, and bars without filling indicate SO42−, NH4+, and NO3, respectively.
Figure A2. Seasonal flux of wet deposition (WD) and throughfall deposition (TF) in 2017. Bars filled with vertical lines, bars filled with bias, and bars without filling indicate SO42−, NH4+, and NO3, respectively.
Forests 12 01798 g0a2

References

  1. Vuorenmaa, J.; Augustaitis, A.; Beudert, B.; Bochenek, W.; Clarke, N.; de Wit, H.A.; Dirnboeck, T.; Frey, J.; Hakola, H.; Kleemola, S.; et al. Long-term changes (1990–2015) in the atmospheric deposition and runoff water chemistry of sulphate, inorganic nitrogen and acidity for forested catchments in Europe in relation to changes in emissions and hydrometeorological conditions. Sci. Total Environ. 2018, 625, 1129–1145. [Google Scholar] [CrossRef] [Green Version]
  2. Vuorenmaa, J.; Augustaitis, A.; Beudert, B.; Clarke, N.; Wit, H.A.d.; Dirnböck, T.; Frey, J.; Forsius, M.; Indriksone, I.; Kleemola, S.; et al. Long-term sulphate and inorganic nitrogen mass balance budgets in European ICP Integrated Monitoring catchments (1990–2012). Ecol. Indic. 2017, 76, 15–29. [Google Scholar] [CrossRef]
  3. Kopacek, J.; Kana, J.; Porcal, P.; Stuchlik, E. Diverse effects of accelerating climate change on chemical recovery of alpine lakes from acidic deposition in soil-rich versus scree-rich catchments. Environ. Pollut. 2021, 284, 117522. [Google Scholar] [CrossRef]
  4. Duan, L.; Yu, Q.; Zhang, Q.; Wang, Z.; Pan, Y.P.; Larssen, T.; Tang, J.; Mulder, J. Acid deposition in Asia: Emissions, deposition, and ecosystem effects. Atmos. Environ. 2016, 146, 55–69. [Google Scholar] [CrossRef] [Green Version]
  5. Aber, J.; McDowell, W.; Nadelhoffer, K.; Magill, A.; Berntson, G.; Kamakea, M.; McNulty, S.; Currie, W.; Rustad, L.; Fernandez, I. Nitrogen saturation in temperate forest ecosystems—Hypotheses revisited. Bioscience 1998, 48, 921–934. [Google Scholar] [CrossRef]
  6. Zhao, W.; Zhao, Y.; Ma, M.; Chang, M.; Duan, L. Long-term variability in base cation, sulfur and nitrogen deposition and critical load exceedance of terrestrial ecosystems in China. Environ. Pollut. 2021, 289, 117974. [Google Scholar] [CrossRef]
  7. Zhao, Y.; Duan, L.; Xing, J.; Larssen, T.; Nielsen, C.P.; Hao, J. Soil Acidification in China: Is Controlling SO2 Emissions Enough? Environ. Sci. Technol. 2009, 43, 8021–8026. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  8. Yu, Q.; Zhang, T.; Ma, X.; Kang, R.; Mulder, J.; Larssen, T.; Duan, L. Monitoring Effect of SO2 Emission Abatement on Recovery of Acidified Soil and Streamwater in Southwest China. Environ. Sci. Technol. 2017, 51, 9498–9506. [Google Scholar] [CrossRef] [PubMed]
  9. Zheng, B.; Tong, D.; Li, M.; Liu, F.; Hong, C.P.; Geng, G.N.; Li, H.Y.; Li, X.; Peng, L.Q.; Qi, J.; et al. Trends in China’s anthropogenic emissions since 2010 as the consequence of clean air actions. Atmos. Chem. Phys. 2018, 18, 14095–14111. [Google Scholar] [CrossRef] [Green Version]
  10. Wen, Z.; Xu, W.; Li, Q.; Han, M.; Tang, A.; Zhang, Y.; Luo, X.; Shen, J.; Wang, W.; Li, K.; et al. Changes of nitrogen deposition in China from 1980 to 2018. Environ. Int. 2020, 144, 106022. [Google Scholar] [CrossRef]
  11. Yu, G.R.; Jia, Y.L.; He, N.P.; Zhu, J.X.; Chen, Z.; Wang, Q.F.; Piao, S.L.; Liu, X.J.; He, H.L.; Guo, X.B.; et al. Stabilization of atmospheric nitrogen deposition in China over the past decade. Nat. Geosci. 2019, 12, 424–429. [Google Scholar] [CrossRef]
  12. Lu, X.; Vitousek, P.M.; Mao, Q.; Gilliam, F.S.; Luo, Y.; Zhou, G.; Zou, X.; Bai, E.; Scanlon, T.M.; Hou, E.; et al. Plant acclimation to long-term high nitrogen deposition in an N-rich tropical forest. Proc. Natl. Acad. Sci. USA 2018, 115, 5187–5192. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  13. Xie, D.; Duan, L.; Si, G.; Liu, W.; Zhang, T.; Mulder, J. Long-Term N-15 Balance After Single-Dose Input of N-15-Labeled NH4+ and NO3- in a Subtropical Forest Under Reducing N Deposition. Glob. Biogeochem. Cycle 2021, 35, e2021GB006959. [Google Scholar] [CrossRef]
  14. Koopmans, C.J.; Lubrecht, W.C.; Tietema, A. Nitrogen transformations in two nitrogen saturated forest ecosystems subjected to an experimental decrease in nitrogen deposition. Plant Soil 1995, 175, 205–218. [Google Scholar] [CrossRef]
  15. Gilliam, F.S.; Burns, D.A.; Driscoll, C.T.; Frey, S.D.; Lovett, G.M.; Watmough, S.A. Decreased atmospheric nitrogen deposition in eastern North America: Predicted responses of forest ecosystems. Environ. Pollut. 2019, 244, 560–574. [Google Scholar] [CrossRef] [PubMed]
  16. Xie, D.N.; Zhang, T.; Yu, Q.; Huang, Y.M.; Mulder, J.; Duan, L. A Sharp Decline in Nitrogen Input in a N-Saturated Subtropical Forest Causes an Instantaneous Reduction in Nitrogen Leaching. J. Geophys. Res. Biogeosci. 2018, 123, 3320–3330. [Google Scholar] [CrossRef]
  17. Huang, Y.; Kang, R.; Mulder, J.; Zhang, T.; Duan, L. Nitrogen saturation, soil acidification, and ecological effects in a subtropical pine forest on acid soil in southwest China. J. Geophys. Res.-Biogeosci. 2015, 120, 2457–2472. [Google Scholar] [CrossRef] [Green Version]
  18. Mitchell, M.J.; Driscoll, C.T.; McHale, P.J.; Roy, K.M.; Dong, Z. Lake/watershed sulfur budgets and their response to decreases in atmospheric sulfur deposition: Watershed and climate controls. Hydrol. Process. 2013, 27, 710–720. [Google Scholar] [CrossRef]
  19. Prechtel, A.; Alewell, C.; Armbruster, M.; Bittersohl, J.; Cullen, J.M.; Evans, C.D.; Helliwell, R.; Kopácek, J.; Marchetto, A.; Matzner, E.; et al. Response of sulphur dynamics in European catchments to decreasing sulphate deposition. Hydrol. Earth Syst. Sci. 2001, 5, 311–326. [Google Scholar] [CrossRef]
  20. Marty, C.; Duchesne, L.; Couture, S.; Gagnon, C.; Houle, D. Effects of climate and atmospheric deposition on a boreal lake chemistry: A synthesis of 36 years of monitoring data. Sci. Total Environ. 2021, 758, 143639. [Google Scholar] [CrossRef]
  21. Larssen, T.; Duan, L.; Mulder, J. Deposition and Leaching of Sulfur, Nitrogen and Calcium in Four Forested Catchments in China: Implications for Acidification. Environ. Sci. Technol. 2011, 45, 1192–1198. [Google Scholar] [CrossRef] [PubMed]
  22. Gao, Y.; Hao, Z.; Han, N.; Yang, J.; Tian, J.; Song, X.; Wen, X.; He, N. Tracking the fate of deposited nitrogen and its redistribution in a subtropical watershed in China. Ecohydrology 2019, 12, e2094. [Google Scholar] [CrossRef]
  23. Wen, X.F.; Wang, H.M.; Wang, J.L.; Yu, G.R.; Sun, X.M. Ecosystem carbon exchanges of a subtropical evergreen coniferous plantation subjected to seasonal drought, 2003–2007. Biogeosciences 2010, 7, 357–369. [Google Scholar] [CrossRef] [Green Version]
  24. Xu, S.G.; Liu, Y.F.; Cui, Y.G.; Pei, Z.Y. Litter decomposition in a subtropical plantation in Qianyanzhou, China. J. Forest Res. 2011, 16, 8–15. [Google Scholar] [CrossRef]
  25. Cheng, Z.; Luo, Y.; Zhang, T.; Duan, L. Deposition of sulfur, nitrogen and mercury in two typical forest ecosystems in southern China. Huanjing Kexue 2017, 38, 5004–5011. [Google Scholar] [CrossRef]
  26. Ke, P.; Yu, Q.; Luo, Y.; Kang, R.; Duan, L. Fluxes of nitrogen oxides above a subtropical forest canopy in China. Sci. Total Environ. 2020, 715, 136993. [Google Scholar] [CrossRef]
  27. Yu, Q.; Luo, Y.; Wang, S.x.; Wang, Z.q.; Hao, J.M.; Duan, L. Gaseous elemental mercury (GEM) fluxes over canopy of two typical subtropical forests in south China. Atmos. Chem. Phys. 2018, 18, 495–509. [Google Scholar] [CrossRef] [Green Version]
  28. Wang, Y.; Wang, H.; Xu, M.; Ma, Z.; Wang, Z.-L. Soil organic carbon stocks and CO2 effluxes of native and exotic pine plantations in subtropical China. Catena 2015, 128, 167–173. [Google Scholar] [CrossRef]
  29. Fu, X.; Wang, J.; Wang, H.; Dai, X.; Yang, F.; Zhao, M. Response of the fine root production, phenology, and turnover rate of six shrub species from a subtropical forest to a soil moisture gradient and shading. Plant Soil 2016, 399, 135–146. [Google Scholar] [CrossRef]
  30. Mo, X.; Dai, X.; Wang, H.; Fu, X.; Kou, L. Rhizosphere effects of overstory tree and understory shrub species in central subtropical plantations-A case study at Qianyanzhou, Taihe, Jiangxi, China. Chin. J. Plant Ecol. 2018, 42, 723–733. [Google Scholar] [CrossRef] [Green Version]
  31. Du, E. A database of annual atmospheric acid and nutrient deposition to China’s forests. Sci. Data 2018, 5, 180223. [Google Scholar] [CrossRef] [Green Version]
  32. Yu, Q.; Duan, L.; Hao, J. Acid deposition in China: Sources, effects and control. Acta Sci. Circumstantiae 2021, 41, 731–746. [Google Scholar]
  33. Yu, Q.; Duan, L.; Yu, L.; Chen, X.; Si, G.; Ke, P.; Ye, Z.; Mulder, J. Threshold and multiple indicators for nitrogen saturation in subtropical forests. Environ. Pollut. 2018, 241, 664–673. [Google Scholar] [CrossRef]
  34. Lin, Y. Water cycling model for ganjiang watershed. Resour. Sci. 1998, 20, 17–23. [Google Scholar]
  35. Fenn, M.E.; Ross, C.S.; Schilling, S.L.; Baccus, W.D.; Larrabee, M.A.; Lofgren, R.A. Atmospheric deposition of nitrogen and sulfur and preferential canopy consumption of nitrate in forests of the Pacific Northwest, USA. Forest Ecol. Manag. 2013, 302, 240–253. [Google Scholar] [CrossRef]
  36. Hao, Z.; Gao, Y.; Zhang, J.-z.; Yu, G.-r. Chemical Characteristics of Atmospheric Wet Deposition in Winter and Its Forestry Canopy Interception Mechanism in Red Soil Hilly Area. Huanjing Kexue 2015, 36, 4403–4413. [Google Scholar]
  37. Vanbreemen, N.; Driscoll, C.T.; Mulder, J. Acidic deposition and internal proton sources in acidification of soils and waters. Nature 1984, 307, 599–604. [Google Scholar] [CrossRef]
  38. Xu, W.; Luo, X.S.; Pan, Y.P.; Zhang, L.; Tang, A.H.; Shen, J.L.; Zhang, Y.; Li, K.H.; Wu, Q.H.; Yang, D.W.; et al. Quantifying atmospheric nitrogen deposition through a nationwide monitoring network across China. Atmos. Chem. Phys. 2015, 15, 12345–12360. [Google Scholar] [CrossRef] [Green Version]
  39. Xing, J.; Lu, X.; Wang, S.; Wang, T.; Ding, D.; Yu, S.; Shindell, D.; Ou, Y.; Morawska, L.; Li, S.; et al. The quest for improved air quality may push China to continue its CO2 reduction beyond the Paris Commitment. Proc. Natl. Acad. Sci. USA 2020, 117, 29535–29542. [Google Scholar] [CrossRef]
  40. Forsius, M.; Posch, M.; Holmberg, M.; Vuorenmaa, J.; Kleemola, S.; Augustaitis, A.; Beudert, B.; Bochenek, W.; Clarke, N.; de Wit, H.A.; et al. Assessing critical load exceedances and ecosystem impacts of anthropogenic nitrogen and sulphur deposition at unmanaged forested catchments in Europe. Sci. Total Environ. 2021, 753, 141791. [Google Scholar] [CrossRef]
  41. Lawrence, G.B.; Scanga, S.E.; Sabo, R.D. Recovery of Soils from Acidic Deposition May Exacerbate Nitrogen Export from Forested Watersheds. J. Geophys. Res.-Biogeosci. 2020, 125, e2019JG005036. [Google Scholar] [CrossRef] [Green Version]
  42. Chen, Y.; Liu, Y.; Lin, Y.; Li, J.; Zhang, H. Hydrological process and nutrient dynamics of schima superba stand in qianyanzhou experimental areas, jiangxi province. Sci. Silvae Sin. 2003, 39, 145–150. [Google Scholar]
  43. National Bureau of Statistics of China. Available online: http://data.stats.gov.cn/ (accessed on 16 August 2021).
  44. Ministry of Ecology and Environment of the People’s Republic of China. Available online: http://www.mee.gov.cn/ (accessed on 16 August 2021).
  45. Corre, M.D.; Lamersdorf, N.P. Reversal of nitrogen saturation after long-term deposition reduction: Impact on soil nitrogen cycling. Ecology 2004, 85, 3090–3104. [Google Scholar] [CrossRef]
  46. Niu, S.; Classen, A.T.; Dukes, J.S.; Kardol, P.; Liu, L.; Luo, Y.; Rustad, L.; Sun, J.; Tang, J.; Templer, P.H.; et al. Global patterns and substrate-based mechanisms of the terrestrial nitrogen cycle. Ecol. Lett. 2016, 19, 697–709. [Google Scholar] [CrossRef] [Green Version]
  47. Galloway, J.N.; Dentener, F.J.; Capone, D.G.; Boyer, E.W.; Howarth, R.W.; Seitzinger, S.P.; Asner, G.P.; Cleveland, C.C.; Green, P.A.; Holland, E.A.; et al. Nitrogen Cycles: Past, Present, and Future. Biogeochemistry 2004, 70, 153–226. [Google Scholar] [CrossRef]
  48. Gao, W.; Kou, L.; Yang, H.; Zhang, J.; Mueller, C.; Li, S. Are nitrate production and retention processes in subtropical acidic forest soils responsive to ammonium deposition? Soil Biol. Biochem. 2016, 100, 102–109. [Google Scholar] [CrossRef]
  49. Liu, W.; Yu, L.; Zhang, T.; Kang, R.; Zhu, J.; Mulder, J.; Huang, Y.; Duan, L. In situ 15N labeling experiment reveals different long-term responses to ammonium and nitrate inputs in N-saturated subtropical forest. J. Geophys. Res. Biogeosci. 2017, 122, 2251–2264. [Google Scholar] [CrossRef] [Green Version]
  50. Zhang, Y.C.; Zhang, J.B.; Meng, T.Z.; Zhu, T.B.; Muller, C.; Cai, Z.C. Heterotrophic nitrification is the predominant NO3 production pathway in acid coniferous forest soil in subtropical China. Biol. Fertil. Soils 2013, 49, 955–957. [Google Scholar] [CrossRef]
  51. Zhang, L.; Luo, Y.; Liu, M.; Chen, Z.; Su, W.; He, H.; Zhu, Z.; Sun, X.; Wang, Y.; Zhou, G.; et al. Carbon and water fluxes observed by the Chinese Flux Observation and Research Network (2003–2005). China Sci. Data 2019, 4, 18–34. [Google Scholar]
  52. Sase, H.; Saito, T.; Takahashi, M.; Morohashi, M.; Yamashita, N.; Inomata, Y.; Ohizumi, T.; Nakata, M. Transboundary air pollution reduction rapidly reflected in stream water chemistry in forested catchment on the sea of Japan coast in central Japan. Atmos. Environ. 2021, 248, 118223. [Google Scholar] [CrossRef]
  53. Sase, H.; Takahashi, M.; Matsuda, K.; Sato, K.; Tanikawa, T.; Yamashita, N.; Ohizumi, T.; Ishida, T.; Kamisako, M.; Kobayashi, R.; et al. Response of river water chemistry to changing atmospheric environment and sulfur dynamics in a forested catchment in central Japan. Biogeochemistry 2019, 142, 357–374. [Google Scholar] [CrossRef]
  54. Wang, Z.; Zhang, X.; Zhang, Y.; Wang, Z.; Mulder, J. Accumulation of different sulfur fractions in Chinese forest soil under acid deposition. J. Environ. Monit. 2011, 13, 2463–2470. [Google Scholar] [CrossRef]
  55. Johnson, D.W. Sulfur cycling in forests. Biogeochemistry 1984, 1, 29–43. [Google Scholar] [CrossRef]
  56. Zhang, W.; Liu, C.-Q.; Wang, Z.-L.; Zhang, L.-L.; Luo, X.-Q. Speciation and Isotopic Composition of Sulfur in Limestone Soil and Yellow Soil in Karst Areas of Southwest China: Implications of Different Responses to Acid Deposition. J. Environ. Qual. 2014, 43, 809–819. [Google Scholar] [CrossRef]
  57. Gustafsson, J.P.; Akram, M.; Tiberg, C. Predicting sulphate adsorption/desorption in forest soils: Evaluation of an extended Freundlich equation. Chemosphere 2015, 119, 83–89. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  58. Houle, D.; Carignan, R.; Ouimet, R. Soil organic sulfur dynamics in a coniferous forest. Biogeochemistry 2001, 53, 105–124. [Google Scholar] [CrossRef]
  59. Shi, S. Eeo-Chemistry of Sulufr under Imapct by Acid Depoistion—A Case Study of Forest Ecosystem ay Mt.Lushan. Ph.D. Thesis, Nanjing Argricutural University, Nanjing, China, 2000. [Google Scholar]
  60. Yu, Q. Fate of Deposited Sulfur and Nitrogen in Typical Subtropical Forest Ecosystems, Southern China. Ph.D. Thesis, Tsinghua University, Beijing, China, 2019. [Google Scholar]
  61. Houle, D.; Marty, C.; Duchesne, L.; Gagnon, C. Humus layer is the main locus of secondary SO4 production in boreal forests. Geochim. Cosmochim. Acta 2014, 126, 18–29. [Google Scholar] [CrossRef]
  62. Mayer, B.; Feger, K.H.; Giesemann, A.; Jager, H.J. Interpretation of sulfur cycling in 2 catchments in the black-forest (germany) using stable sulfur and oxygen-isotope data. Biogeochemistry 1995, 30, 31–58. [Google Scholar] [CrossRef]
  63. Mayer, B.; Prietzel, J.; Krouse, H.R. The influence of sulfur deposition rates on sulfate retention patterns and mechanisms in aerated forest soils. Appl. Geochem. 2001, 16, 1003–1019. [Google Scholar] [CrossRef]
  64. Yu, Q.; Si, G.; Zong, T.; Mulder, J.; Duan, L. High hydrogen sulfide emissions from subtropical forest soils based on field measurements in south China. Sci. Total Environ. 2019, 651, 1302–1309. [Google Scholar] [CrossRef]
Forests 12 01798 g001 550
Figure 1. Seasonal water fluxes (a), SO42− concentrations (a), SO42− fluxes (b), DIN concentrations (c), and DIN fluxes (d) of wet deposition (WD), throughfall deposition (TF), and soil water in the top layer (S5, 5 cm depth), 15 cm (S15), and below the root zone (S30, 30 cm depth) in 2018. Bars filled with vertical lines and bias are SO42− and NH4+, respectively, and bars without filling are NO3. Error bars are standard errors.
Figure 1. Seasonal water fluxes (a), SO42− concentrations (a), SO42− fluxes (b), DIN concentrations (c), and DIN fluxes (d) of wet deposition (WD), throughfall deposition (TF), and soil water in the top layer (S5, 5 cm depth), 15 cm (S15), and below the root zone (S30, 30 cm depth) in 2018. Bars filled with vertical lines and bias are SO42− and NH4+, respectively, and bars without filling are NO3. Error bars are standard errors.
Forests 12 01798 g001
Forests 12 01798 g002 550
Figure 2. Yearly depositions of SO42− (a), DIN (b), NO3 (c), and NH4+ (d) via wet deposition (WD), throughfall deposition (TF), and dry deposition (DD) to forests at Qianyanzhou station. Data in 2000, 2014, and 2015 are attained from Refs. [22,25,42], respectively, with the same sampling method. The error bars and shadowed area are standard errors and total emissions of related air pollutants in Jiangxi Province [43,44], respectively.
Figure 2. Yearly depositions of SO42− (a), DIN (b), NO3 (c), and NH4+ (d) via wet deposition (WD), throughfall deposition (TF), and dry deposition (DD) to forests at Qianyanzhou station. Data in 2000, 2014, and 2015 are attained from Refs. [22,25,42], respectively, with the same sampling method. The error bars and shadowed area are standard errors and total emissions of related air pollutants in Jiangxi Province [43,44], respectively.
Forests 12 01798 g002
Table
Table 1. Retention and excess S and N output 1 and H+ production along the soil profile in 2018.
Table 1. Retention and excess S and N output 1 and H+ production along the soil profile in 2018.
SeasonLayer of Soil 2Soil Water Flux (mm)Excess S Output (kg S/ha)Excess N Output (kg N/ha)H+prod, N (kmol/ha)
Spring0–5 cm3081.87 ± 0.852.19 ± 0.413.60 ± 0.41
5–15 cm1782.12 ± 2.36−0.40 ± 0.710.02 ± 0.71
15–30 cm190−0.46 ± 2.22−1.37 ± 0.65−0.86 ± 0.65
Summer0–5 cm3163.62 ± 0.671.23 ± 0.666.08 ± 0.66
5–15 cm2553.40 ± 1.652.52 ± 1.152.58 ± 1.15
15–30 cm240−2.77 ± 1.51−2.59 ± 1.00−2.83 ± 1.00
Autumn0–5 cm1301.06 ± 0.910.08 ± 0.562.87 ± 0.56
5–15 cm115−0.52 ± 1.380.68 ± 1.001.12 ± 1.00
15–30 cm58−1.23 ± 1.07−1.7 ± 0.94−1.85 ± 0.94
Winter0–5 cm2024.32 ± 0.711.18 ± 0.493.71 ± 0.49
5–15 cm149−1.16 ± 1.5−0.62 ± 0.850.12 ± 0.85
15–30 cm138−1.93 ± 1.34−2.63 ± 0.78−2.11 ± 0.78
Annual0–5 cm95710.87 ± 1.584.68 ± 1.0816.26 ± 1.08
5–15 cm6973.83 ± 3.532.18 ± 1.883.85 ± 1.88
15–30 cm626−6.37 ± 3.18−8.29 ± 1.71−7.65 ± 1.71
1 Calculated as difference between leaching flux in the layer and the upper layer or the throughfall input for topsoil (0–5 cm). For N, both NO3 and NH4+ were included. Positive values indicated excess export, otherwise nutrient retention or gaseous loss in the soil. 2 Excess export at S5, S15, and S30 were considered as from the topsoil, root zone, and deeper soil (below the root zone), respectively.
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Ke, P.; Si, G.; Luo, Y.; Cheng, Z.; Yu, Q.; Duan, L. Soil Nitrogen and Sulfur Leaching in a Subtropical Forest at a Transition State under Decreasing Atmospheric Deposition. Forests 2021, 12, 1798. https://0-doi-org.brum.beds.ac.uk/10.3390/f12121798

AMA Style

Ke P, Si G, Luo Y, Cheng Z, Yu Q, Duan L. Soil Nitrogen and Sulfur Leaching in a Subtropical Forest at a Transition State under Decreasing Atmospheric Deposition. Forests. 2021; 12(12):1798. https://0-doi-org.brum.beds.ac.uk/10.3390/f12121798

Chicago/Turabian Style

Ke, Piaopiao, Gaoyue Si, Yao Luo, Zhenglin Cheng, Qian Yu, and Lei Duan. 2021. "Soil Nitrogen and Sulfur Leaching in a Subtropical Forest at a Transition State under Decreasing Atmospheric Deposition" Forests 12, no. 12: 1798. https://0-doi-org.brum.beds.ac.uk/10.3390/f12121798

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop