Impact of increased water and salt on nitrogen dynamics in soil pore water of the Minjiang River estuary wetland

doi:10.13287/j.1001-9332.202510.019

Abstract

Abstract: Estuarine wetlands, functioning as dynamic interfaces among terrestrial, atmospheric, and marine systems, are critical components of global nitrogen cycle. Here, we examined the effects of increased salinity and inundation induced by seawater intrusion on total nitrogen (TN), inorganic nitrogen fractions in soil pore water, as well as the physicochemical properties of soil and pore water in the brackish Cyperus malaccensis wetland in Shanyutan of the Minjiang River Estuary, by conducting an experiment with three treatments, control (bare soil,CK), tidal water (flooding depth 5 cm, salinity 2-11, TW), and saline water (flooding depth 5 cm, salinity 15, SW). The result showed that: 1) TW treatment reduced the contents of NO₃^--N and NO₂^--N in soil pore water by 30.0% and 25.0%, respectively. The SW treatment reduced the contents of nitrate nitrogen (NO₃^--N), nitrite nitrogen (NO₂^--N), and TN in soil pore water by 65.0%, 50.0%, and 16.1%, respectively, while slightly increased the ammo-nium nitrogen (NH₄⁺-N) content by 8.7%. 2) TN was positively correlated with soil temperature but negatively correlated with soil moisture. NH₄⁺-N was significantly positively correlated with soil temperature and negatively correlated with pore water pH and soil moisture, whereas NO₃^--N exhibited a significant negative correlation with soil temperature. 3) The structural equation modeling (SEM) analysis indicated that salinity had a significant negative and direct effect on NO₃^--N and NO₂^--N, and a significant positive and direct effect on NH₄⁺-N. Increased water-salinity coupling induced by seawater intrusion would more strongly affect nitrogen transformations in soil pore water by suppressing nitrification and promoting denitrification, thereby accelerating nitrogen loss in the estuarine wetland.

Key words: inorganic nitrogen, total nitrogen, seawater intrusion, Minjiang River Estuary wetland

YU Yanping, WANG Chun, WANG Yafei, ZHANG Yushuo, WANG Weiqi, TONG Chuan. Impact of increased water and salt on nitrogen dynamics in soil pore water of the Minjiang River estuary wetland[J]. Chinese Journal of Applied Ecology, 2025, 36(10): 2936-2944.

References

[1] Khoddamzadeh AA, Flores J, Griffith PM, et al. Saltwater intrusion ecophysiological effects on Pseudophoenix sargentii, Roystonea regia, Sabal palmetto “Lisa,” and Thrinax radiata in South Florida. Frontiers in Ecology and Evolution, 2023, 11: 1127679
[2] Putnam Duhon LA, Gambrell RP, Rusch KA, et al. Effects of salinity on the microbial removal of nitrate under varying nitrogen inputs within the marshland upwelling system.Journal of Environmental Science and Health, 2012, 47: 1739-1748
[3] Galloway JN, Townsend AR, Erisman JW, et al. Transformation of the nitrogen cycle: Recent trends, questions, and potential solutions. Science, 2008, 320: 889-892
[4] Canfield DE, Glazer AN, Falkowski PG. The evolution and future of earth’s nitrogen cycle. Science, 2010, 330: 192-196
[5] Deegan LA, Johnson DS, Warren RS, et al. Coastal eutrophication as a driver of salt marsh loss. Nature, 2012, 490: 388-392
[6] Wang HT, Gilbert JA, Zhu YG, et al. Salinity is a key factor driving the nitrogen cycling in the mangrove sediment. Science of the Total Environment, 2018, 631-632: 1342-1349
[7] Jia J, Bai JH, Gao HF, et al. Effects of salinity and moisture on sediment net nitrogen mineralization in salt marshes of a Chinese estuary. Chemosphere, 2019, 228: 174-182
[8] Jun M, Altor AE, Craft CB. Effects of increased salinity and inundation on inorganic nitrogen exchange and phosphorus sorption by tidal freshwater floodplain forest soils, Georgia (USA). Estuaries and Coasts, 2013, 36: 508-518
[9] Zhou MH, Butterbach-Bahl K, Vereecken H, et al. A meta-analysis of soil salinization effects on nitrogen pools, cycles and fluxes in coastal ecosystems. Global Change Biology, 2017, 23: 1338-1352
[10] Weston NB, Giblin AE, Banta GT, et al. The effects of varying salinity on ammonium exchange in estuarine sedi-ments of the Parker River, Massachusetts. Estuaries and Coasts, 2010, 33: 985-1003
[11] Ardón M, Morse JL, Colman BP, et al. Drought-induced saltwater incursion leads to increased wetland nitrogen export. Global Change Biology, 2013,19: 2976-2985
[12] van Dijk G, Smolders AJP, Loeb R, et al. Salinization of coastal freshwater wetlands: Effects of constant versus fluctuating salinity on sediment biogeochemistry. Biogeochemistry, 2015, 126: 71-84
[13] 谢蓉蓉, 李家兵, 张党玉, 等. 闽江河口湿地沉积物氮矿化对盐度响应研究. 中国环境科学, 2017, 37(6): 2248-2254
[14] Hu WF, Zhang WL, Zhang LH, et al. Short-term changes in simulated inundation frequency differentially affect inorganic nitrogen, nitrification, and denitrification in estuarine marshes. Ecological Indicators, 2019, 107: 105571
[15] Santoro AE. Microbial nitrogen cycling at the saltwater-freshwater interface. Hydrogeology Journal, 2010, 18: 187-202
[16] Tschikof M, Gericke A, Venohr M, et al. The potential of large floodplains to remove nitrate in river basins: The Danube case. Science of the Total Environment, 2022, 843: 156879
[17] 刘剑秋, 曾从盛, 陈宁. 闽江河口湿地研究. 北京: 科学出版社, 2006
[18] Stachelek J, Kelly SP, Sklar FH, et al. In situ simulation of sea-level rise impacts on coastal wetlands using a flow-through mesocosm approach. Methods in Ecology and Evolution, 2018, 9: 1908-1915
[19] Wang C, Sardans J, Tong C, et al. Typhoon-induced increases in porewater nutrient concentrations and CO₂ and CH₄ emissions associated with salinity and carbon intrusion in a subtropical tidal wetland in China: A mesocosm study. Geoderma, 2021, 384: 114800
[20] 国家海洋信息中心. 2022年中国海平面公报[EB/OL]. (2023-04-14)[2025-05-06]. https://www.nmdis.org.cn/hygb/zghpmgb/2022nzghpmgb/
[21] 中华人民共和国生态环境部. 水质总氮的测定碱性过硫酸钾消解紫外分光光度法: HJ 636—2012. 北京: 中国环境科学出版社, 2012
[22] 中华人民共和国生态环境部. 水质氨氮的测定水杨酸分光光度法: HJ 536—2009. 北京: 中国环境科学出版社, 2009
[23] 中华人民共和国生态环境部. 水质硝酸盐氮的测定镉柱还原法: HJ/T 198—2005. 北京: 中国环境科学出版社, 2005
[24] 中华人民共和国生态环境部. 水质亚硝酸盐氮的测定分光光度法: GB/T 7493—1987. 北京: 中国环境科学出版社, 1987
[25] Kiehn WM, Mendelssohn IA, White JR. Biogeochemical recovery of oligohaline wetland soils experiencing a salinity pulse. Soil Science Society of America Journal, 2013, 77: 2205-2215
[26] Zhou ZJ, Ge L, Huang YF, et al. Coupled relationships among anammox, denitrification, and dissimilatory nitrate reduction to ammonium along salinity gradients in a Chinese estuarine wetland. Journal of Environmental Sciences, 2021, 106: 39-46
[27] Li P, Lang M, Wei W, et al. Reduction of gross N transformations to moisture changes in a wetland ecosystem: The case of marshland conversion to cropland. Wetlands, 2023, 43: 16
[28] 周易, 程淑兰, 方华军, 等. 泥炭地土壤氮排放对气候暖干化响应研究进展. 应用生态学报, 2024, 35(6): 1725-1734
[29] Correa MD, Schnabela RR, Stou WL. Spatial and seasonal variation of gross nitrogen transformations and microbial biomass in Northeastern US grassland. Soil Biology and Biochemistry, 2002, 34: 445-457
[30] Gao HF, Bai JH, Deng XY, et al. Short-term effects of tidal flooding on soil nitrogen mineralization in a Chinese tidal salt marsh. Physics and Chemistry of the Earth, 2017, 103: 3-10
[31] Abbas T, Zhang QC, Jin H, et al. Anammox microbial community and activity changes in response to water and dissolved oxygen managements in a paddy-wheat soil of Southern China. Science of the Total Environment, 2019, 672: 305-313
[32] 王纯, 陈晓旋, 陈优阳, 等. 水盐梯度对闽江河口湿地土壤水稳性团聚体分布及稳定性的影响. 环境科学学报, 2019, 39(9): 3117-3125
[33] Bai JH, Yu L, Du SD, et al. Effects of flooding frequencies on soil carbon and nitrogen stocks in river marginal wetlands in a ten-year period. Journal of Environmental Management, 2020, 267: 110618
[34] Luo SY, Yuan JB, Song YY, et al. Elevated salinity decreases microbial communities complexity and carbon, nitrogen and phosphorus metabolism in the Songnen Plain wetlands of China.Water Research, 2025,276: 123285
[35] Lodhi A, Arshad M, Azam F, et al. Changes in mineral and mineralizable N of soil incubated at varying salinity, moisture and temperature regimes. Pakistan Journal of Botany, 2009, 41: 967-980
[36] Jiang YH, Yin GY, Li Y, et al. Saltwater incursion regu-lates N₂O emission pathways and potential nitrification and denitrification in intertidal wetland. Biology and Fertility of Soils, 2023, 59: 541-553
[37] Kool DM, Wrage N, Zechmeister-Boltenstern S, et al. Nitrifier denitrification can be a source of N₂O from soil: A revised approach to the dual-isotope labelling method. European Journal of Soil Science, 2010, 61: 759-772
[38] Meng YY, He ZB, Liu B, et al. Soil salinity and moisture control the processes of soil nitrification and denitrification in a riparian wetlands in an extremely arid regions in Northwestern China. Water, 2020, 12: 2815
[39] Li XF, Gao DZ, Hou LJ, et al. Salinity stress changed the biogeochemical controls on CH₄ and N₂O emissions of estuarine and intertidal sediments. Science of the Total Environment, 2019, 652: 593-601
[40] 李志丽, 王红梅, 赵亚楠, 等. 荒漠草原灌丛引入过程中土壤氮矿化的季节动态及其影响因子. 应用生态学报, 2023, 34(8): 2161-2170
[41] Giblin AE, Weston NB, Banta GT, et al. The effects of salinity on nitrogen losses from an oligohaline estuarine sediment. Estuaries and Coasts, 2010, 33: 1054-1068
[42] Widney SE, Smith D, Herbert ER, et al. Chronic but not acute saltwater intrusion leads to large release of inorganic N in a tidal freshwater marsh. Science of the Total Environment, 2019, 695: 133779
[43] El-Hefnawy ME, Selim EM, Assaad FF, et al. The effect of chloride and sulfate ions on the adsorption of Cd²⁺ on clay and sandy loam Egyptian soils. Scientific World Journal, 2014, 2014: 806252
[44] 刘超毅, 何凌茜, 黄庄, 等. 模拟盐度脉冲耦合潮汐过程对闽江河口湿地土壤孔隙水中无机氮组分的影响. 湿地科学, 2023, 21(3): 483-492
[45] Neubauer SC, Franklin RB, Berrier DJ. Saltwater intrusion into tidal freshwater marshes alters the biogeochemical processing of organic carbon. Biogeosciences, 2013, 10: 8171-8183
[46] Grace JB. Structural Equation Modeling and Natural Systems. Cambridge, UK: Cambridge University Press, 2006
[47] Xie RR, Lin LC, Shi CC, et al. Elucidating the links between N₂O dynamics and changes in microbial communities following saltwater intrusions. Environmental Research, 2024, 245: 118021
[48] Banerjee S, Helgason B, Wang LF, et al. Legacy effects of soil moisture on microbial community structure and N₂O emissions. Soil Biology and Biochemistry, 2016, 95: 40-50
[49] 解丽娜, 李亚雷, 李诗华, 等. 本土和外来湿地植物土壤微生物生物量对水、盐胁迫的响应. 生态科学, 2020, 39(6): 181-190
[50] Du YH, Guo P, Liu JQ, et al. Different types of nitrogen deposition show variable effects on the soil carbon cycle process of temperate forests. Global Change Biology, 2014, 20: 3222-3228
[51] Bahram M, Hildebrand F, Forslund SK, et al. Structure and function of the global topsoil microbiome. Nature, 2018, 560: 233-237
[52] Meng CB, Xing YT, Ding Y, et al. Soil acidification induced variation of nitrifiers and denitrifiers modulates N₂O emissions in paddy fields. Science of the Total Environment, 2023, 822: 163623