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Carbon storage of a subtropical forest ecosystem: a case study of the Jinggang Mountain National Nature Reserve in south-eastern China

  • Jiping Zhang
  • Linbo Zhang
  • Haiguang Hao
  • Chunlan Liu
  • Hui Wang
Original Paper
  • 33 Downloads

Abstract

The carbon cycle of forest ecosystems plays a key role in regulating CO2 concentrations in the atmosphere. Research on carbon storage estimation of forest ecosystems has become a major research topic. However, carbon budgets of subtropical forest ecosystems have received little attention. Reports of soil carbon storage and topographic heterogeneity of carbon storage are limited. This study focused on the Jinggang Mountain National Nature Reserve as an example of a mid-subtropical forest and evaluated soil and vegetation carbon storage by field sampling combined with GIS, RS and GPS technology. We classified the forest into nine forest types using ALOS high-resolution remote sensing images. The evergreen broad-leaved forest has the largest area, occupying 26.5% of the total area, followed by coniferous and broad-leaved mixed forests and warm temperate coniferous forest, occupying 24.2 and 22.9%, respectively. The vegetation and soil carbon storage of the whole forest ecosystem were 1,692,344 and 5,514,707 t, with a carbon density of 7.4 and 24.2 kg/m2, respectively, which suggests that the ecosystem has great carbon storage capacity. The topographic heterogeneity of the carbon storage was also analysed. The largest vegetation storage and soil storage is at 700–800 and 1000–1100 m, respectively. The vegetation carbon storage is highest in the southeast, south and southwest.

Keywords

Vegetation carbon storage Soil carbon storage Mid-subtropical forest ecosystem Jinggang Mountain National Nature Reserve 

References

  1. Aahen CW, Arun JN, Yadava PS (2018) Aboveground biomass and carbon stock in the largest sacred grove of Manipur, Northeast India. J For Res 29:425–428CrossRefGoogle Scholar
  2. Ao XY, Zhan YS, Lin F, Yu MG, Shao JF (1999) Key soil types and nutrient of evergreen broad-leaved forest in Jiangxi Province, China. Jiangxi For Sci Technol 40:4–6 (in Chinese) Google Scholar
  3. Baker FD (2008) Reassessing carbon sinks. Science 317:1708–1709Google Scholar
  4. Behling H (2002) Carbon storage increases by major forest ecosystems in tropical South America since the Last Glacial Maximum and the early Holocene. Glob Planet Change 33:107–116CrossRefGoogle Scholar
  5. Berrien M, Braswell BH (1994) Earth metabolism: understanding carbon cycling. AMBIO 23:4–12Google Scholar
  6. Brown S, Lugo AE (1984) Biomass of tropical forests: a new estimate based on forest volumes. Science 223:1290–1293CrossRefPubMedGoogle Scholar
  7. Cao MK, Tao B, Li KR, Shao XM, Stephen DP (2003) Inter annual variation in terrestrial ecosystem carbon fluxes in China from 1981 to 1998. Acta Bot Sin 45:552–560Google Scholar
  8. Dixon RK, Brown S, Houghton RA, Solomon AM, Trexler MC, Wisniewski J (1994) Carbon pools and fluxes of global forest ecosystems. Science 263:185–190CrossRefPubMedGoogle Scholar
  9. Fang JY, Oikawa T, Kato T, Mo W, Wang ZH (2005) Biomass carbon accumulation by Japan’s forests from 1947–1995. Global Biogeochem Cycles 19:1–10CrossRefGoogle Scholar
  10. Guo ZD, Fang JY, Pan Y, Birdsey R (2010) Inventory-based estimates of forest biomass carbon stocks in China: a comparison of three methods. For Ecol Manag 259(7):1225–1231CrossRefGoogle Scholar
  11. Guo JM, Zheng BF, Hu LL, Lin W (2011) Comparison of soil organic carbon density and its factors between two typical forest types in Jinggang Mountain. Ecol Environ Sci 20:1836–1840 (in Chinese) Google Scholar
  12. Hay GJ, Blaschke T, Marceau DJ (2003) A comparison of three image-object methods for the multi-scale analysis of landscape structure. ISPRS J Photogramm Remote Sens 57:327–345CrossRefGoogle Scholar
  13. Hoover CM, Leak WB, Keel BG (2012) Benchmark carbon stocks from old-growth forests in northern New England, USA. For Ecol Manag 266:108–114CrossRefGoogle Scholar
  14. Houghton RA, Skole DL, Nobre CA (2000) Annual fluxes of carbon from deforestation and regrowth in the Brazilian Amazon. Nature 403:301–304CrossRefPubMedGoogle Scholar
  15. Hu LL, Lin W, Luo ZL, Guo JM, Fan JT, Li JS (2011) Comparison of carbon densities of five dominant forest ecosystems on Jinggang Mountain. Res Environ Sci 24:401–408 (in Chinese) Google Scholar
  16. IPCC (2000) The science of climate change. Cambridge University Press, Cambridge, pp 5–10Google Scholar
  17. Jamshid E, Hormoz S (2018) Carbon storage in biomass, litter, and soil of different native and introduced fast-growing tree plantations in the South Caspian Sea. J For Res 29:449–457CrossRefGoogle Scholar
  18. Keiichi A, Toshiya Y, Ha Akane, Mahoko N, Hisashi M, Hideaki S (2011) Changes in carbon stock following soil scarification of non-wooded stands in Hokkaido, northern Japan. J For Res 16:35–45CrossRefGoogle Scholar
  19. Lal R (2005) Forest soils and carbon sequestration. Ecol Manag 220:242–258CrossRefGoogle Scholar
  20. Li HK, Lei YC (2010) Estimation and evaluation of forest biomass carbon storage in China. Chinese Forestry Press, Beijing, p 41 (in Chinese) Google Scholar
  21. Li MH, Yu MJ, Chen QC, Chang J, Pan XD (1996) Dynamics of carbon in the evergreen broad-leaved forest dominated by Cyclobalanopsis glauca in South–East China. Acta Ecol Sin 16:645–651 (in Chinese) Google Scholar
  22. Li YQ, Xu M, Zou XM, Shi PJ, Zhang YQ (2005) Comparing soil organic carbon dynamics in plantations and secondary forest in wet tropics in Puerto Rico. Change Biol 11:239–248CrossRefGoogle Scholar
  23. Li HT, Wang SN, Gao LP, Yu GR (2007) The carbon storage of the subtropical forest vegetation in central Jiangxi Province. Acta Ecol Sin 27:693–704 (in Chinese) Google Scholar
  24. Lin SM, Xu TG, Zhou GM (1991) Study on biomass of Cunninghamia lanceolata plantations. J Zhejiang For Coll 8:288–294 (in Chinese) Google Scholar
  25. Lin W, Li JS, Zheng BF, Guo JM, Hu LL (2010) Models for estimating biomass of twelve shrub species in Jinggang Mountain Nature Reserve. J Wuhan Bot Res 28:725–729 (in Chinese) Google Scholar
  26. Liu QX, Chang J, Jiang B, Yuan WG, Qi LZ, Zhu JR, Ge Y, Shen Q (2005) The biomass of the evergreen broad-leaved ecological public-welfare forests in Zhejiang, East China. Acta Ecol Sin 25:2139–2144 (in Chinese) Google Scholar
  27. Liu YC, Wang QF, Yu GR, Zhu XJ, Zhan XY, Guo Q, Yang H, Li SG, Hu ZM (2011) Ecosystems carbon storage and carbon sequestration potential of two main tree species for the Grain for Green Project on China’s hilly Loess Plateau. Acta Ecol Sin 31:4277–4286 (in Chinese) Google Scholar
  28. Lü X, Yin JX, Jepsen MR, Tang JW (2010) Ecosystem carbon storage and partitioning in a tropical seasonal forest in Southwestern China. For Ecol Manag 260:1798–1803CrossRefGoogle Scholar
  29. Lun F, Li WH, Liu Y (2012) Complete forest carbon cycle and budget in China, 1999 − 2008. For Ecol Manag 264:81–89CrossRefGoogle Scholar
  30. Ma XQ, Liu CJ, Hannu L, Carl JW, Liu AQ (2002) Biomass, litter fall and the nutrient fluxes in Chinese fir stands of different age in subtropical China. J For Res 13:165–170CrossRefGoogle Scholar
  31. Martin JL, Gower ST, Plaut J, Holmes B (2003) Carbon pools in a boreal mixed wood logging chronosequence. Glob Change Biol 11:188–199Google Scholar
  32. McGarvey JC, Thompson JR, Epstein HE, Shugart HH (2016) Carbon storage in old-growth forests of the mid-atlantic: toward better understanding the eastern forest carbon sink. Ecology 96:311–317CrossRefGoogle Scholar
  33. Murillo J (1997) Temporal variations in the carbon budget of forest ecosystems in Spain. Ecol Appl 7:461–469CrossRefGoogle Scholar
  34. Peng CH, Jiang H, Apps MJ, Zhang YL (2002) Effects on harvesting regimes on carbon and nitrogen dynamics of boreal forests in central Canada: a process model simulation. Ecol Model 155:177–189CrossRefGoogle Scholar
  35. Schiewe J, Tufte L, Ehlers M (2001) Potential and problems of multi-scale segmentation methods in remote sensing. GeoB IT/GIS 6:34–39Google Scholar
  36. Schimel DS (1995) Terrestrial ecosystems and the carbon cycle. Glob Change Biol 1:77–91CrossRefGoogle Scholar
  37. Scholes RJ, Nobel IR (2001) Storing carbon on land. Science 294:1012–1013CrossRefPubMedGoogle Scholar
  38. Seedre M, Shrestha BM, Chen HYH, Colombo S, Jõgiste K (2011) Carbon dynamics of North American boreal forest after stand replacing wildfire and clear cut logging. J For Res 16:168–183CrossRefGoogle Scholar
  39. Sharma CM, Baduni NP, Gairola S, Ghildiyal SK, Suyal S (2010) Tree diversity and carbon stocks of some major forest types of Garhwal Himalaya, India. For Ecol Manag 260:2170–2179CrossRefGoogle Scholar
  40. Sundquist ET (1993) The global carbon dioxide budget. Science 259:935–941CrossRefGoogle Scholar
  41. Taki S, Nobori Y, Caceres MLL (2014) Method for estimation of stem carbon fixation of Japanese black pine by combining stem analysis and soft X-ray densitometry. J For Res 19:226–232CrossRefGoogle Scholar
  42. Usuga JL, Toro JR, Alzate MR, Tapias AL (2010) Estimation of biomass and carbon stocks in plants in plants, soil and forest floor in different tropical forests. For Ecol Manag 260:1906–1913CrossRefGoogle Scholar
  43. Wang YX (1999) Study on regional carbon cycle of forest ecosystem in China. In: Collection of Ph.D. Thesis of committee of synthesis investigation of natural resources. Chinese Academy of Sciences, Beijing, pp 156–272 (in Chinese)Google Scholar
  44. Wang XK, Feng ZY, Ouyang ZY (2001) The impact of human disturbance on vegetative carbon storage in forest ecosystems in China. For Ecol Manag 148:117–123CrossRefGoogle Scholar
  45. Wang SQ, Zhou CH, Liu JY, Tian HQ, Li KR, Yang XM (2002) Carbon storage in northeast China as estimated from vegetation and soil inventories. Environ Pollut 116:157–165CrossRefGoogle Scholar
  46. Wang YF, Liu L, Shangguan ZP (2018) Dynamics of forest biomass carbon stocks from 1949 to 2008 in Henan Province, east-central China. J For Res 29:439–448CrossRefGoogle Scholar
  47. Waring RH, Running SW (2007) Forest ecosystems: analysis at multiple scales. Elsevier/Academic Press, Amsterdam/Boston, p 85Google Scholar
  48. Yue K, Fornara DA, Yang WQ, Peng Y, Peng CH, Liu ZL, Wu FZ (2017) Influence of multiple global change drivers on terrestrial carbon storage: additive effects are common. Ecol Lett 20:663–672CrossRefPubMedGoogle Scholar
  49. Zhang J, Ge Y, Chang J, Jiang B, Jiang H, Peng CH, Zhu JR, Yuan WG, Qi LZ, Yu SQ (2007) Carbon storage by ecological service forests in Zhejiang Province, subtropical China. For Ecol Manag 245:64–75CrossRefGoogle Scholar
  50. Zhang K, Xu XN, Wang Q, Liu B (2010) Biomass, and carbon and nitrogen pools in a subtropical evergreen broad-leaved forest in eastern China. J For Res 15:274–282CrossRefGoogle Scholar
  51. Zhang L, Yu GR, Gu FX, He HL, Zhang LM, Han SJ (2012) Uncertainty analysis of modeled carbon fluxes for a broad-leaved Korean pine mixed forest using a process-based ecosystem model. J For Res 17:268–282CrossRefGoogle Scholar
  52. Zhang JP, Liu CL, Hao HG, Qiao Q, Wang H, Sun L (2015) Object-oriented classification of subtropical forest based on ALOS high resolution remote sensing image. South China For Sci 43:39–42 (in Chinese) Google Scholar
  53. Zheng H, Ouyang ZY, Xu WH, Wang XK, Miao H, Li XQ, Tian YX (2008) Variation of carbon storage by different reforestation types in the hilly red soil region of southern China. For Ecol Manag 255:1113–1121CrossRefGoogle Scholar
  54. Zhou YR, Yu ZL, Zhao SD (2000) Carbon storage and budget of major Chinese forest types. Acta Phytoecol Sin 24:518–522 (in Chinese) Google Scholar
  55. Zhou CY, Wei XH, Zhou GY, Yan JH, Wang X, Wang CL, Liu HG, Tang XY, Zhang QM (2008) Impacts of a large-scale reforestation program on carbon storage dynamics in Guangdong, China. For Ecol Manag 225:847–854CrossRefGoogle Scholar

Copyright information

© Northeast Forestry University and Springer-Verlag GmbH Germany, part of Springer Nature 2018

Authors and Affiliations

  • Jiping Zhang
    • 1
  • Linbo Zhang
    • 2
  • Haiguang Hao
    • 2
  • Chunlan Liu
    • 1
  • Hui Wang
    • 1
  1. 1.Beijing Municipal Research Institute of Environmental ProtectionBeijingPeople’s Republic of China
  2. 2.Chinese Research Academy of Environmental SciencesBeijingPeople’s Republic of China

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