Abstract
Leaf carbon content (LCC) is widely used as an important parameter in estimating ecosystem carbon (C) storage, as well as for investigating the adaptation strategies of vegetation to their environment at a large scale. In this study, we used a dataset collected from forests (5119 plots) and shrublands (2564 plots) in China, 2011–2015. The plots were sampled following a consistent protocol, and we used the data to explore the spatial patterns of LCC at three scales: plot scale, eco-region scale (n = 24), and eco-region scale (n = 8). The average LCC of forests and shrublands combined was 45.3%, with the LCC of forests (45.5%) being slightly higher than that of shrublands (44.9%). Forest LCC ranged from 40.2% to 51.2% throughout the 24 eco-regions, while that of shrublands ranged from 35% to 50.1%. Forest LCC decreased with increasing latitude and longitude, whereas shrubland LCC decreased with increasing latitude, but increased with increasing longitude. The LCC increased, to some extent, with increasing temperature and precipitation. These results demonstrate the spatial patterns of LCC in the forests and shrublands at different scales based on field-measured data, providing a reference (or standard) for estimating carbon storage in vegetation at a regional scale.
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References
Bert D, Danjon F, 2006. Carbon concentration variations in the roots, stem and crown of mature Pinus pinaster (Ait.). Forest Ecology & Management, 222(1–3): 279–295.
Birdsey R A, 1992. Carbon storage and accumulation in United States forest ecosystems. In: General Technical Report. Washington D.C, U.S.: Department of Agriculture, Forest Service, Washington Office.
Chapin F S, Matson P A, Mooney H A, 2002. Principles of Terrestrial Ecosystem Ecology. New York, USA: Springer.
Cheng T R, Feng J, Ma Q Y et al., 2008. Carbon pool and allocation of forest vegetation in Xiaolong Mountains, Gansu Province. Acta Ecologica Sinica, 28(1): 33–44. (in Chinese)
Du H M, Wang C, Gao H Z, 2009. Carbon-sink function of artificial Larix principis-rupprechtii plantation. Chinese Journal of Eco-Agriculture, 17(4): 756–759. (in Chinese)
Ehleringer J R, Field C B, 1993. Scaling Physiological Processes: Leaf to Globe. Vol. 261. San Diego: Academic Press.
Fang J Y, Chen A P, Peng C H et al., 2001. Changes in forest biomass carbon storage in China between 1949 and 1998. Science, 292(5525): 2320–2322.
Fu B J, Liu G H, Chen L D et al., 2001. Scheme of ecological regionalization in China. Acta Ecologica Sinica, 21(1): 1–6. (in Chinese)
Fu Y, Sun Y J, 2013. A study of the determination of organic carbon of vegetation. World Forestry Research, 26(1): 24–30. (in Chinese)
Han W X, Wu Y, Tang L Y et al., 2009. Leaf carbon, nitrogen and phosphorus stoichiometry across plant species in Beijing and its periphery. Acta Scientiarum Naturalium Universitatis Pekinensis, 45(5): 855–860. (in Chinese)
Houghton R A, Skole D L, Nobre C A et al., 2000. Annual uxes of carbon from deforestation and regrowth in the Brazilian Amazon. Nature, 403(6767): 301–304.
Jagodzinski A M, Jarosiewicz G, Karolewski P et al., 2012. Carbon concentration in the biomass of common species of understory shrubs. Sylwan, 156(9): 650–662.
Liu G H, Fu B J, Fang J Y, 2000. Carbon dynamics of Chinese forests and its contribution to global carbon balance. Acta Ecologica Sinica, 20(5): 733–740. (in Chinese)
Ma Q Y, Chen X L, Wang J et al., 2002. Carbon content rate in constructive species of main forest types in northern China. Journal of Beijing Forestry University, 24(Suppl.1): 96–100. (in Chinese)
Navar J, 2009. Allometric equations for tree species and carbon stocks for forests of northwestern Mexico. Forest Ecology and Management, 257(2): 427–434.
Ren S J, Yu G R, Jiang C M et al., 2012. Stoichiometric characteristics of leaf carbon, nitrogen, and phosphorus of 102 dominant species in forest ecosystems along the North-South Transect of East China. Chinese Journal of Applied Ecology, 23(3): 581–586. (in Chinese)
Shvidenko A Z, Nilsson S, Rojkov V A et al., 1996. Carbon budget of the Russian boreal forests: A systems analysis approach to uncertainty. Apps M J, Price D T. Vol.40. Berlin 33: Springer-Verlag Berlin.
Sykes M T, Prentice I C, 1996. Carbon storage and climate change in Swedish forests: A comparison of static and dynamic modelling approaches. Apps M J, Price D T. Vol. 40. Berlin 33: Springer-Verlag Berlin.
Tolunay D, 2009. Carbon concentrations of tree components, forest floor and understorey in young Pinus sylvestris stands in north-western Turkey. Scandinavian Journal of Forest Research, 24(5): 394–402.
Turner D P, Koerper G J, Harmon M E et al., 1995. A carbon budget for forests of the conterminous United States. Ecological Applications, 5(2): 421–436.
Wang J L, Wang X H, Yue C R et al., 2012. Carbon content rate in dominant species of four forest types in Shangrila, northwest Yunnan province. Ecology and Environmental Sciences, 21(4): 613–619. (in Chinese)
Wang S Q, Yu G R, 2008. Ecological stoichiometry characteristics of ecosystem carbon, nitrogen and phosphorus elements. Acta Ecologica Sinica, 28(8): 3937–3947. (in Chinese)
Wang X K, Feng Z W, Ouyang Z Y, 2001. Vegetation carbon storage and density of forest ecosystems in China. Chinese Journal of Applied Ecology, 12(1): 13–16. (in Chinese)
Xie Z Q, Tang Z Y, Zhao C M et al., 2015. Observation and Investigation for Carbon Sequestration in Shrub Ecosystemss. Beijing: Science Press. (in Chinese)
Yang C H, 2001. Plant Geography. Beijing: Science Press. (in Chinese)
Yang Y J, Chen Y M, Cao Y, 2014. Carbon density and distribution of Pinus tabulaeformis plantation ecosystem in hilly Loess Plateau. Acta Ecologica Sinica, 34(8): 2128–2136. (in Chinese)
Yerena-Yamallel J I, J Jiménez-Pérez, O A Aguirre-Calderón et al., 2011. ConcentraciÓn De Carbono En La Biomasa AÉrea Del Matorral Espinoso Tamaulipeco. Revista Chapingo Serie Ciencias Forestales Y Del Ambiente, XVII(2): 283–291.
Yu G R, Ren W, Chen Z et al., 2016. Construction and progress of Chinese terrestrial ecosystem carbon, nitrogen and water fluxes coordinated observation. Journal of Geograhical Sciences, 26(7): 803–826.
Yu Y, Fan W Y, Li M Z, 2012. Forest carbon rates at different scales in Northeast China forest area. Chinese Journal of Applied Ecology, 23(2): 341–346. (in Chinese)
Zhao M, Yue T, Na Z et al., 2014. Combining LPJ-GUESS and HASM to simulate the spatial distribution of forest vegetation carbon stock in China. Journal of Geographical Sciences, 24(2): 249–268.
Zheng W J, Bao W K, Gu B et al., 2007. Carbon concentration and its characteristics in terrestrial higher plants. Chinese Journal of Ecology, 26(3): 307–313. (in Chinese)
Zhou G Y, Wen D Z, Tang X L et al., 2015. Observation and Investigation for Carbon Sequestration in Forest Ecosystemss. Beijing: Science Press. (in Chinese)
Zhou Y R, Yu Z L, Zhao S D, 2000. Carbon storage and budget of major Chinese forest types. Acta Phytoecologica Sinica, 24(5): 518–522. (in Chinese)
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Foundation: National Key R&D Program of China, No.2016YFA0600103, No.2017YFA0604803; Youth Innovation Research Team Project, No.LENOM2016Q0005
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Zhao, H., Xu, L., Wang, Q. et al. Spatial patterns and environmental factors influencing leaf carbon content in the forests and shrublands of China. J. Geogr. Sci. 28, 791–801 (2018). https://doi.org/10.1007/s11442-018-1505-x
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DOI: https://doi.org/10.1007/s11442-018-1505-x