Effects of water and nitrogen addition on vegetation carbon pools in a semi-arid temperate steppe

Junqiang Jia; Yunshe Dong; Yuchun Qi; Qin Peng; Xinchao Liu; Liangjie Sun; Shufang Guo; Yunlong He; Congcong Cao; Zhongqing Yan

doi:10.1007/s11676-015-0128-7

Journal of Forestry Research ›› 2015, Vol. 27 ›› Issue (3) : 621 -629. DOI: 10.1007/s11676-015-0128-7

Original Paper

Effects of water and nitrogen addition on vegetation carbon pools in a semi-arid temperate steppe

Junqiang Jia ¹^,²
, Yunshe Dong ¹^,^b
, Yuchun Qi ¹^,^c
, Qin Peng ¹
, Xinchao Liu ¹^,³
, Liangjie Sun ¹^,⁴
, Shufang Guo ¹^,²
, Yunlong He ¹^,²
, Congcong Cao ¹^,²
, Zhongqing Yan ¹^,²

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Abstract

Global change will lead to increases in regional precipitation and nitrogen (N) deposition in the semi-arid grasslands of northern China. We investigated the responses of vegetation carbon (C) pools to simulated precipitation and N deposition increases through field experiments in a typical steppe in Inner Mongolia. The treatments included NH₄NO₃ addition at concentrations of 0 (CK), 5 (LN, low nitrogen), 10 (middle nitrogen, MN), and 20 (HN, high nitrogen) (g m⁻² a⁻¹) with and without water. After three consecutive years of treatment, from 2010 to 2012, water addition did not significantly change the size of the total vegetation C pools, but it significantly decreased the ratio of root:shoot (R:S) (P = 0.05) relative to controls. By contrast, N addition significantly increased the total vegetation C pools. The C pools in the LN, MN and HN treatments increased by 22, 39 and 44 %, respectively. MN produced the largest effect among the N concentrations, although differences between N-added treatments were not significant (P > 0.05). N addition significantly reduced the ratio of root:shoot (R:S) (P = 0.03). However, there were no significant interactive effects of water and N addition on the vegetation C pools.

Keywords

Vegetation carbon pools / Increasing precipitation / Nitrogen addition / Interactive effect / Temperate steppe

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Junqiang Jia, Yunshe Dong, Yuchun Qi, Qin Peng, Xinchao Liu, Liangjie Sun, Shufang Guo, Yunlong He, Congcong Cao, Zhongqing Yan. Effects of water and nitrogen addition on vegetation carbon pools in a semi-arid temperate steppe. Journal of Forestry Research, 2015, 27(3): 621-629 DOI:10.1007/s11676-015-0128-7

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Arens SJT, Sullivan PF. Nonlinear responses to nitrogen and strong interactions with nitrogen and phosphorus additions drastically alter the structure and function of a high arctic ecosystem. J Geophys Res, 2008, 113 G03S09

[2]	Asner GP, Elmore AJ, Olander LP, Martin RE, Harris AT. Grazing systems, ecosystem responses and global change. Annu Rev Environ Resour, 2004, 29: 261-299.

[3]	Austin AT, Yahdjian L, Stark JM, Belnap J, Porporato A, Norton U. Water pulses and biogeochemical cycles in arid and semi-arid ecosystems. Oecologia, 2004, 141: 221-235.

[4]	Bai YF, Han XG, Wu JG, Chen ZZ, Li LH. Ecosystem stability and compensatory effects in the Inner Mongolia grassland. Nature, 2004, 431: 181-184.

[5]	Bai YF, Wu JG, Clark CM, Naeem S, Pan QM, Huang JH, Zhang LX, Han XG. Tradeoffs and thresholds in the effects of nitrogen addition on biodiversity and ecosystem functioning: evidence from Inner Mongolia grasslands. Glob Chang Biol, 2010, 16: 358-372.

[6]	Bardgett RD, Mawdsley JL, Edwards S, Hobbs PJ, Rodwell JS, Davies WJ. Plant species and nitrogen effects on soil biological properties of temperate upland grasslands. Funct Ecol, 1999, 13: 650-660.

[7]	Beer C, Reichstein M, Tomelleri E, Ciais P. Terrestrial gross carbon dioxide uptake: global distribution and co-variation with climate. Science, 2010, 329: 834-838.

[8]	Bell C, Mclntyre N, Cox S, Tissue D, Zak J. Soil microbial responses to temporal variations of moisture and temperature in a Chihuahuan Desert grassland. Microb Ecol, 2008, 56: 153-167.

[9]	Belnap J. Belnap J, Lange OL. Microbes and microfauna associated with biological soil crusts. Biological soil crusts: structure, function, and management. 2001, Berlin: Springer, 167 174

[10]	Brown KR, Thompson WA, Camm EL. Effects of N addition rates on the productivity of Picea sitchensis, Thuja plicata, and Tsuga heterophylla seedlings. Trees, 1996, 10: 198-205.

[11]	Carvalhais LC, Dennis PG, Fedoseyenko D, Hajirezaei MR, Borriss R. Root exudation of sugars, amino acids and organic acids by maize as affected by nitrogen, phosphorus, potassium and iron deficiency. J Plant Nutr Soil Sci, 2011, 174: 3-11.

[12]	Chen ZZ, Wang SP. Typical grassland ecosystem in China. 2000, Beijing: Science Press, 1.

[13]	Chen SP, Bai YF, Zhang LX, Han XG. Comparing physiological responses of two dominant grass species to nitrogen addition in Xilin River Basin of China. Environ Exp Bot, 2005, 53: 65-75.

[14]	Craine JM, Gelderman TM. Soil moisture controls on temperature sensitivity of soil organic carbon decomposition for a mesic grassland. Soil Biol Biochem, 2011, 43: 455-457.

[15]	Dalgleish HJ, Hartnett DC. Below-ground bud banks increase along a precipitation gradient of the North American Great Plains: a test of the meristem limitation hypothesis. New Phytol, 2006, 171: 81-89.

[16]	Dentener F, Drevet J, Lamarque JF. Nitrogen and sulfur deposition on regional and global scales: a multi-model evaluation. Glob Biogeochem Cycles, 2006, 20 GB4003

[17]	Dukes JS, Chiariello NR, Cleland EE. Responses of grassland production to single and multiple global environmental changes. PLoS Biol, 2005, 3: 1829-1837.

[18]	Foster BL, Gross KL. Species richness in a successional grassland: effects of nitrogen enrichment and plant litter. Ecology, 1998, 79: 2593-2602.

[19]	Galloway JN, Cowling EB. Reactive nitrogen and the world: 200 years of change. Ambio, 2002, 31: 64-71.

[20]	Giese M, Gao YG, Zhao Y, Pan QM, Lin S, Peth S, Brueck H. Effects of grazing and rainfall variability on root and shoot decomposition in a semi-arid grassland. Appl Soil Ecol, 2009, 41: 8-18.

[21]	Gough L, Osenberg CW, Gross KL, Collins SL. Fertilization effects on species density and primary productivity in herbaceous plant communities. Oikos, 2000, 89: 428-439.

[22]	Groenigen KJ, Osenberg CW, Hungate BA. Increased soil emissions of potent greenhouse gases under increased atmospheric CO₂. Nature, 2011, 475: 214-216.

[23]	Guo R, Wang XK, Ouyang ZY, Li YN. Spatial and temporal relationships between precipitation and ANPP of four types of grasslands in northern China. J Environ Sci, 2006, 18(5): 1024-1030.

[24]	Harpole WS, Goldstein L, Aicher R. D’Antonio C, Corbin J, Stromberg M. Resource limitation. Ecology and management of California grassland. 2007, Berkeley: University of California Press, 119 127

[25]	Hautier Y, Niklaus PA, Hector A. Competition for light causes plant biodiversity loss after eutrophication. Science, 2009, 324: 636-638.

[26]	IPCC Climate change 2001: the scientific basis. 2001, Cambridge: Cambridge University Press, 4.

[27]	IPCC Climate change 2007: the physical science basis. 2007, Cambridge: Cambridge University Press, 27 940

[28]	Jiang ZH, Zhang X, Wang J. Projection of climate change in China in the 21st century by IPCC-AR4 models. Geogr Res, 2008, 27(4): 787-799.

[29]	Jin Z, Qi YC, Dong YS. Diurnal and seasonal dynamics of soil respiration in desert shrubland of Artemisia Ordosica on Ordos Plateau of Inner Mongolia, China. J For Res, 2007, 18(3): 231-235.

[30]	Joiner JY, Yoshida Y, Vasilkov AP, Yoshida Y, Corp LA, Middleton EM. First observations of global and seasonal terrestrial chlorophyll fluorescence from space. Biogeosciences, 2011, 8: 637-651.

[31]	Kuzyakov Y, Domanski G. Carbon input by plants into the soil. J Plant Nutr Soil Sci, 2000, 163: 421-431.

[32]	Le Houérou HN, Bingham RL, Skerbek W. Relationship between the variability of primary production and the variability of annual precipitation in world arid lands. J Arid Environ, 1988, 15: 1-18.

[33]	LeBauer DS, Treseder KK. Nitrogen limitation of net primary productivity in terrestrial ecosystems is globally distributed. Ecology, 2008, 89: 371-379.

[34]	Li DJ, Mong JM, Fang YT. Impact of nitrogen deposition on forest plants. Acta Ecol Sin, 2003, 23(9): 1892-1900.

[35]	Malhi Y. The productivity, metabolism and carbon cycle of tropical forest vegetation. J Ecol, 2012, 100: 65-75.

[36]	Maston PA, McDowell WH, Townsen AR. The globalization of N deposition: ecosystem consequences in tropical environments. Biogeochemistry, 1999, 46: 67-83.

[37]	Nakaji T, Fukami M, Dokiya Y. Effects of high nitrogen load on growth, photosynthesis and nutrient status of Cryptom eria japonica and Pinus densiflora seedlings. Trees-Struct Funct, 2001, 15(8): 453-461.

[38]	Pan QM, Bai YF, Han XG, Yang JC. Effects of nitrogen additions on a leymus chinensis population in a typical steppe of Inner Mongolia. Acta Phytoecol Sin, 2005, 29: 311-317.

[39]	Peng Q, Qi YC, Dong YS. Decomposing litter and the C and N dynamics as affected by N additions in a semi-arid temperate steppe, Inner Mongolia of China. J Arid Land, 2014, 6(4): 432-444.

[40]	Phillips OL, Aragão LEOC, Lewis SL, Fisher JB. Drought sensitivity of the Amazon rainforest. Science, 2009, 323: 1344-1347.

[41]	Piao SL, Fang JY, He JS, Xiao Y. Spatial distribution of grassland biomass in China. Acta Phytoecol Sin, 2004, 28(4): 491-498.

[42]	Potts DL, Huxman TE, Cable JM. Antecedent moisture and seasonal precipitation influence the response of canopy-scale carbon and water exchange to rainfall pulses in a semi-arid grassland. New Phytol, 2006, 170: 849-860.

[43]	Qi Y, Huang YM, Wang Y. Biomass and its allocation of four grassland species under different nitrogen levels. Acta Ecol Sin, 2011, 31(18): 5121-5129.

[44]	Qi YC, Liu XC, Dong YS. Differential responses of short-term soil respiration dynamics to the experimental addition of nitrogen and water in the temperate semi-arid steppe of Inner Mongolia, China. J Environ Sci, 2014, 26: 834-845.

[45]	Rao LE, Allen EB. Combined effects of precipitation and nitrogen deposition on native and invasive winter annual production in California deserts. Oecologia, 2010, 62: 1035-1046.

[46]	Reichstein M, Bahn M, Ciais P, Frank D, Mahecha MD, Sonia I, Martin W. Climate extremes and the carbon cycle. Nature, 2013, 500(5): 287-295.

[47]	Ryals R, Silver WL. Effects of organic matter amendments on net primary productivity and greenhouse gas emissions in annual grasslands. Ecol Appl, 2013, 23: 46-69.

[48]	Schlesinger. Carbon balance in terrestrial detritus. Annu Rev Ecol Syst, 1977, 8: 51-81.

[49]	Sims PL, Singh JS. The structure and function of ten western North American grasslands. III. Net primary production, turnover and efficiencies of energy capture and water use. J Ecol, 1978, 66: 573-597.

[50]	Song CJ, Ma KM, Qu LY. Interactive effects of water, nitrogen and phosphorus on the growth, biomass partitioning and water-use efficiency of Bauhinia faberi seedlings. J Arid Environ, 2010, 2010: 1-10.

[51]	Swemmer AM, Knapp AK, Snyman HA. Intra-seasonal precipitation patterns and above-ground productivity in three perennial grasslands. J Ecol, 2007, 95: 780-788.

[52]	Thomas RQ, Canham CD, Weathers KC, Goodale CL. Increased tree carbon storage in response to nitrogen deposition in the US. Nat Geosci, 2010, 3: 13-17.

[53]	Tian YS, Guo YY, Zhang PD. Relationship of regional net primary productivity and related meteorological factors. Pratacult Sci, 2010, 27(2): 8-17.

[54]	Tu LH, Hu TX, Huang LH. Response of soil respiration to simulated nitrogen deposition in Pleioblastus Amarus forest, rainy area of west China. Chin J Plant Ecol, 2009, 33(4): 728-738.

[55]	Van Auken OW. Causes and consequences of woody plant encroachment into western North American grasslands. J Environ Manag, 2009, 90: 2931-2942.

[56]	Vitousek PM, Howarth RW. Nitrogen limitation on land and in the sea: how can it occur?. Biogeochemistry, 1991, 13: 87-115.

[57]	Wang YH, Zhou GS. Responses of temporal dynamics of aboveground net primary productivity of Leymus chinensis community to precipitation fluctuation in Inner Mongolia. Acta Ecol Sin, 2004, 24(6): 1140-1145.

[58]	Wang L, Niu KC, Yang YH. Patterns of above- and belowground biomass allocation in China’s grasslands: evidence from individual-level observations. Sci China Ser C, 2010, 53(7): 851-857.

[59]	Warren A, Sud YC, Rozanov B. The future of deserts. J Arid Environ, 1996, 32: 75-89.

[60]	Wedin DA, Tilman D. Influence of nitrogen loading and species composition on the carbon balance of grasslands. Science, 1996, 274: 1720-1723.

[61]	Wen MZ. The status and prospect of grassland source utilization in Chinese eco-agriculture. Agro-Environ Dev, 1996, 13: 14-18.

[62]	Wen X, Hou XY, Mu HB. Effects of irrigation amount on alfalfa productivity in south of Beijing. Pratacult Sci, 2010, 27(4): 73-77.

[63]	Wu ZT. Responses of terrestrial ecosystems to temperature and precipitation change: a meta-analysis of experimental manipulation. Glob Chang Biol, 2011, 17: 927-942.

[64]	Xia JY, Wan SQ. Global response patterns of terrestrial plant species to nitrogen addition. New Phytol, 2008, 179: 428-439.

[65]	Xiao SS. The responses of carbon fixation and soil organic carbon pool to external nitrogen input in the temperate semi-arid grassland ecosystem. 2010, Beijing: University of Chinese Academy of Sciences, 48 50

[66]	Xu ZZ, Zhou GS. EV ects of water stress and high nocturnal temperature on photosynthesis and nitrogen level of a perennial grass Leymus chinensis. Plant Soil, 2005, 269: 131-139.

[67]	Yu L, Piao SL. Key scientific points on carbon and other biogeochemical cycles from the IPCC fifth assessment report. Progressus Inquisitiones De Mutatione Climatis, 2014, 10(1): 33-36.

[68]	Yu ZY, Zeng DH, Jang FQ. Responses of biomass to the addition of water, nitrogen and phosphorus in Keerqin sandy grassland, Inner Mongolia, China. J For Res, 2009, 20(1): 23-26.

[69]	Zeng DH, Li LJ, Fahey TJ, Yu ZY, Fan ZP, Chen FS. Effects of nitrogen addition on vegetation and ecosystem carbon in a semi-arid grassland. Biogeochemistry, 2010, 98: 185-193.

[70]	Zhang XS, Zhou GS, Gao Q, Yang DA, Ni J, Wang Q. Northeast China Transect (NECT) for global change studies. Earth Sci Front, 1997, 4: 145-151.

[71]	Zhang W, Mo JM, Fang YT, Lu XK, Wang H. Effects of nitrogen deposition on the greenhouse gas fluxes from forest soils. Acta Ecol Sin, 2008, 28: 2309-2319.

[72]	Zhao GY, Liu JS, Wang Y, Dou JX, Dong XY. Effects of elevated CO₂ concentration and nitrogen supply on biomass and active carbon of freshwater marsh after two growing seasons in Sanjiang Plain, Northeast China. J Environ Sci, 2009, 21: 1393-1399.