Abstract
Soil organic carbon (OC) is sensitive to climatic change, and it can be expected to manifest measurable responses to global warming. Globally, nitrogen (N) and phosphorus (P) are the most common nutrients limiting plant growth and soil carbon storage. We collected soil samples at 17 marsh sites in August 2012 across Northeast China. These samples were analysed for variations in soil organic carbon (OC), total nitrogen (TN) and total phosphorus (TP) levels, and multiple controlling of environmental and biotic factors. Results showed the means to be as follows: 16,850.7 mmol kg−1 (OC), 540.5 mmol kg−1 (TN), 30.0 mmol kg−1 (TP), 29.9 (C:N), 516.5 (C:P) and 16.8 (N:P). The OC, TN, TP and C:N:P ratios decreased with increases in the mean annual temperature (MAT) and flooding depth, whereas the C:N ratio did not change significantly with the flooding depth. Quadratic relationships were observed between the OC, TN and TP and soil pH. Linear mixed-effect models showed that climate exerted great influences on soil nutrients. These results will improve our understanding of the ecological patterns of nutrient fluxes and the biogeochemical mechanisms of the response of vegetation to climate changes.
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References
Aerts R, Chapin F III (2000) The mineral nutrition of wild plants revisited. Advances in Ecological Research 30:1–67
Ajwa H, Rice C, Sotomayor D (1998) Carbon and nitrogen mineralization in tallgrass prairie and agricultural soil profiles. Soil Science Society of America Journal 62(4):942–951
Bai J, Deng W, Zhu Y, Luan Z, Zhang Y (2003) Spatial distribution characteristics and ecological effects of carbon and nitrogen of soil in Huolin River catchment wetland. The Journal of Applied Ecology 14(9):1494–1498 (in Chinese)
Bai J, Ouyang H, Deng W, Zhu Y, Zhang X, Wang Q (2005) Spatial distribution characteristics of organic matter and total nitrogen of marsh soils in river marginal wetlands. Geoderma 124(1):181–192
Bridgham SD, Updegraff K, Pastor J (1998) Carbon, nitrogen, and phosphorus mineralization in northern wetlands. Ecology 79(5):1545–1561
Brinson MM, Bradshaw HD, Kane ES (1984) Nutrient assimilative capacity of an alluvial floodplain swamp. Journal of Applied Ecology:1041–1057
Bui EN, Henderson BL (2013) C: N: P stoichiometry in Australian soils with respect to vegetation and environmental factors. Plant and Soil 373(1–2):553–568
Chadwick OA, Derry L, Vitousek PM, Huebert BJ, Hedin LO (1999) Changing sources of nutrients during four million years of ecosystem development. Nature 397(6719):491–497
Cleveland CC, Liptzin D (2007) C: N: P stoichiometry in soil: is there a “Redfield ratio” for the microbial biomass? Biogeochemistry 85(3):235–252
Craft C, Broome S, Seneca E (1988) Nitrogen, phosphorus and organic carbon pools in natural and transplanted marsh soils. Estuaries 11(4):272–280
Crawford ER, Day FP, Atkinson RB (2007) Influence of environment and substrate quality on root decomposition in naturally regenerating and restored Atlantic white cedar wetlands. Wetlands 27(1):1–11
Elser JJ, Fagan WF, Kerkhoff AJ, Swenson NG, Enquist BJ (2010) Biological stoichiometry of plant production: metabolism, scaling and ecological response to global change. The New Phytologist 186(3):593–608
Fan H, Wu J, Liu W, Yuan Y, Hu L, Cai Q (2015) Linkages of plant and soil C: N: P stoichiometry and their relationships to forest growth in subtropical plantations. Plant and Soil 392(1–2):127–138
Fierer N, Jackson RB (2006) The diversity and biogeography of soil bacterial communities. Proceedings of the National Academy of Sciences of the United States of America 103(3):626–631
Finzi AC, Austin AT, Cleland EE, Frey SD, Houlton BZ, Wallenstein MD (2011) Responses and feedbacks of coupled biogeochemical cycles to climate change: examples from terrestrial ecosystems. Frontiers in Ecology and the Environment 9(1):61–67
Gao J, Xu X, Zhang F, Wang C (2008) Distribution characteristics of soil labile carbon along water table gradient of alpine wetland soils. Journal of Soil and Water Conservation 22(3):126–131 (in Chinese)
Gao Y, Chen H, Zeng X (2014) Effects of nitrogen and sulfur deposition on CH4 and N2O fluxes in high-altitude peatland soil under different water tables in the Tibetan plateau. Soil Science & Plant Nutrition 60(3):404–410
Gorham E (1991) Northern peatlands: role in the carbon cycle and probable responses to climatic warming. Ecological Applications 1(2):182–195
Guo X, Lu X, Tong S, Dai G (2008) Influence of environment and substrate quality on the decomposition of wetland plant root in the Sanjiang plain, Northeast China. Journal of Environmental Sciences 20(12):1445–1452
He C (2003) Dynamics of litter and under-ground biomass in Carex lasiocarpa wetland on Sanjiang plain. The Journal of Applied Ecology 14(3):363–366 (in Chinese)
Huang R (1994) Environment Pedology. Advanced Education Press, Beijing, pp. 145–146
Jenny H (1941) Factors of soil formation. McGraw-Hill Book Co. Inc, New York, NY
Jia Q, Zhou L, Xie Y, Zhou G (2006) Study on biomass dynamics of Phragmites communis community in Panjin wetland. Journal of Meteorology and Environment 22:25–29 (in Chinese)
Jiao F, Wen Z-M, An S-S, Yuan Z (2013) Successional changes in soil stoichiometry after land abandonment in Loess Plateau, China. Ecological Engineering 58:249–254
Jobbágy EG, Jackson RB (2000) The vertical distribution of soil organic carbon and its relation to climate and vegetation. Ecological Applications 10(2):423–436
Li Z, Sun B, Lin X (2001) Density of soil organic carbon and the factors controlling its turnover in East China. Geographical. Science 21(4):301–301 (in Chinese)
Liu X (2005) Wetlands in Northern China. Science Press, Beijing, p. 9 (in Chinese)
Lu X (2008) Wetland ecosystem study in China. Hebei Sience and Technology Publishing House, Hebei, p. 338
McGroddy ME, Daufresne T, Hedin LO (2004) Scaling of C:N:P stoichiometry in forests worldwide: implications of terrestrial redfield-type ratios. Ecology 85(9):2390–2401. doi:10.1890/03-0351
Melillo JM, Butler S, Johnson J, Mohan J, Steudler P, Lux H, Burrows E, Bowles F, Smith R, Scott L (2011) Soil warming, carbon–nitrogen interactions, and forest carbon budgets. Proceedings of the National Academy of Sciences 108(23):9508–9512
Mitsch WJ, Gosselink JG (2007) Wetlands, 4th edn. Wiley, Hoboken
Nakagawa S, Schielzeth H (2013) A general and simple method for obtaining R2 from generalized linear mixed-effects models. Methods in Ecology and Evolution 4(2):133–142
Novak M, Brizova E, Adamova M, Erbanova L, Bottrell SH (2008) Accumulation of organic carbon over the past 150 years in five freshwater peatlands in western and Central Europe. Science of the Total Environment 390(2):425–436
Patrick W, Khalid R (1974) Phosphate release and sorption by soils and sediments: effect of aerobic and anaerobic conditions. Science 186(4158):53–55
Paul EA (2014) Soil microbiology, ecology and biochemistry. Academic Press, New York
Peñuelas J, Sardans J, Rivas-ubach A, Janssens IA (2012) The human-induced imbalance between C, N and P in Earth’s life system. Global Change Biology 18(1):3–6
Penuelas J, Poulter B, Sardans J, Ciais P, van der Velde M, Bopp L, Boucher O, Godderis Y, Hinsinger P, Llusia J (2013) Human-induced nitrogen-phosphorus imbalances alter natural and managed ecosystems across the globe. Nature Communications 4:2934
Qin S, Liu J, Sun Z (2006) Dynamics of phosphorus and biomass accumulation of Calamagrostis angustifolia in Sanjiang plain. Journal of Applied Ecology 25(6):646–651 (in Chinese)
Qu F, Yu J, Du S, Li Y, Lv X, Ning K, Wu H, Meng L (2014) Influences of anthropogenic cultivation on C, N and P stoichiometry of reed-dominated coastal wetlands in the Yellow River Delta. Geoderma 235:227–232
R Development Core Team (2016) R: a language and environment for statistical computing, R version 3.3.1. R Foundation for Statistical Computing, Vienna. http://www.R-project.org/
Ramsar (2013) The Ramsar manual, 6th-ed edn. Ramsar Convention Secretariat, Switzerland, p. 110
Reddy K, Diaz O, Scinto L, Agami M (1995) Phosphorus dynamics in selected wetlands and streams of the Lake Okeechobee Basin. Ecological Engineering 5(2):183–207
Rivas-Ubach A, Sardans J, Pérez-Trujillo M, Estiarte M, Peñuelas J (2012) Strong relationship between elemental stoichiometry and metabolome in plants. Proceedings of the National Academy of Sciences 109(11):4181–4186
Schlesinger WH, Cole JJ, Finzi AC, Holland EA (2011) Introduction to coupled biogeochemical cycles. Frontiers in Ecology and the Environment 9(1):5–8
Shang Z, Feng Q, Wu G, Ren G, Long R (2013) Grasslandification has significant impacts on soil carbon, nitrogen and phosphorus of alpine wetlands on the Tibetan Plateau. Ecological Engineering 58:170–179
Sparks DL, Page A, Helmke P, Loeppert R, Soltanpour P, Tabatabai M, Johnston C, Sumner M (1996) Methods of soil analysis. Part 3-Chemical methods. Soil Science Society of America Inc.
Steinman AD, Ogdahl ME, Weinert M, Thompson K, Cooper MJ, Uzarski DG (2012) Water level fluctuation and sediment–water nutrient exchange in Great Lakes coastal wetlands. Journal of Great Lakes Research 38(4):766–775
Sterner RW, Elser JJ (2002) Ecological stoichiometry: the biology of elements from molecules to the biosphere. Princeton University Press, Princeton
Sun Z, Liu J (2007) Nitrogen cycling of atmosphere-plant-soil system in the typical Calamagrostis angustifolia wetland in the Sanjiang plain, Northeast China. Journal of Environmental Sciences 19(8):986–995
Tian H, Chen G, Zhang C, Melillo JM, Hall CA (2010) Pattern and variation of C: N: P ratios in China’s soils: a synthesis of observational data. Biogeochemistry 98(1–3):139–151
Updegraff K, Pastor J, Bridgham SD, Johnston CA (1995) Environmental and substrate controls over carbon and nitrogen mineralization in northern wetlands. Ecological Applications 5(1):151–163
van Oorschot M, van Gaalen N, Maltby E, Mockler N, Spink A, Verhoeven JT (2000) Experimental manipulation of water levels in two French riverine grassland soils. Acta Oecologica 21(1):49–62
Vitousek PM, Howarth RW (1991) Nitrogen limitation on land and in the sea: how can it occur? Biogeochemistry 13(2):87–115
Vitousek PM, Porder S, Houlton BZ, Chadwick OA (2010) Terrestrial phosphorus limitation: mechanisms, implications, and nitrogen-phosphorus interactions. Ecological Applications 20(1):5–15
Wang W (2007) Spatical parterns of soil nutrients and their response to grazing disturbance over the Songnen meadow steppes of NE China. Northeast Normal University, pp. 59 (in Chinese)
Wang F, Song M, Huang M, Zhang J (2014) The spatial distribution of soil nutrients and the controlling factors of temperate forest and steppe in Northeastern China. Ecology and. Environmental Sciences 23(8):1280–1285 (in Chinese)
Wang W, Wang C, Sardans J, Tong C, Jia R, Zeng C, Peñuelas J (2015) Flood regime affects soil stoichiometry and the distribution of the invasive plants in subtropical estuarine wetlands in China. Catena 128:144–154
Xiao H (1999) Climate change in relation to soil organic matter. Soil and Environmental Sciences 4:014
Xiao Y, Shang L, Huang Z, Zhang W, Xue Z, Zhang Z, Lu X (2014) Ecological stoichiometry characteristics of soil carbon, nitrogen and phosphorous in mountain swamps of eastern Jilin province. Scientia Geographica Sinica 34(8):994–1001 (in Chinese)
Xu X, Thornton PE, Post WM (2013) A global analysis of soil microbial biomass carbon, nitrogen and phosphorus in terrestrial ecosystems. Global Ecology and Biogeography 22(6):737–749
Yang G, Zhang W, Tong C, Wu J (2005) Effects of temperature on the mineralization of organic carbon in sediment of wetland. Acta Ecologica Sinica 25(2):343–348 (in Chinese)
Yang Y, Fang J, Guo D, Ji C, Ma W (2010) Vertical patterns of soil carbon, nitrogen and carbon: nitrogen stoichiometry in Tibetan grasslands. Biogeosciences Discussions 7:1–24
Yu J, Wang J, Liu J, Qi X, Wang Y (2002) Effect of soil pH value variation on effective content of trace elemments in typical black soil. Journal of Soil and Water Conservation 16(2):93–95 (in Chinese)
Zhang Y, Yang Y, Wang L (2006) Studies on seasonal dynamics of production and allocation in Phragmites australis population in Sanjiang wetland plain. Chinese Journal of Grassland 28(4):1–5 (in Chinese)
Zhang Z, Lu X, Song X, Guo Y, Xue Z (2012) Soil C, N and P stoichiometry of Deyeuxia angustifolia and Carex lasiocarpa wetlands in Sanjiang plain, Northeast China. Journal of Soils and Sediments 12(9):1309–1315
Zhang ZS, Song XL, Lu XG, Xue ZS (2013) Ecological stoichiometry of carbon, nitrogen, and phosphorus in estuarine wetland soils: influences of vegetation coverage, plant communities, geomorphology, and seawalls. Journal of Soils and Sediments 13(6):1043–1051
Zhao K (1999) Chinese marsh. Science Press, Beijing (in Chinese)
Zhao S, Yu W, Zhang L, Shen S (2005) Latitudinal differentiation of phosphorus in black soil in Northeast of China. Chinese society of. Agricultural Engineering 21:34–37 (in Chinese)
Zhao H, Liu W, Wang X, Cai Y, Du Z (2014) Distribution of soil carbon and nitrogen under different water conditionsin alpine salty wetlands, northern Tibet Plateau. Mountain. Research 32(4):431–437 (in Chinese)
Acknowledgements
This research was supported by the National Natural Science Foundation of China (Nos. 41371107, 41271106) and the National Key Technology R & D Program (2012BAC19B05). We thank Dr. Andrew Revill for language edit and Dr. Zhi Ding for a drawing of a map.
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Liu, Y., Jiang, M., Lu, X. et al. Carbon, Nitrogen and Phosphorus Contents of Wetland Soils in Relation to Environment Factors in Northeast China. Wetlands 37, 153–161 (2017). https://doi.org/10.1007/s13157-016-0856-2
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DOI: https://doi.org/10.1007/s13157-016-0856-2