Phosphorus biological cycle in the different Suaeda salsa marshes of the Yellow River estuary, China
详细信息    查看全文
  • 作者:Zhigao Sun (1)
    Xiaojie Mou (1)
    Hanqin Tian (2)
    Hongli Song (1)
    Huanhuan Jiang (1)
    Jinyong Zhao (3)
    Wanlong Sun (1)
    Wenguang Sun (1)
  • 关键词:Phosphorus ; Biological cycle ; Suaeda salsa marsh ; Yellow River estuary
  • 刊名:Environmental Earth Sciences
  • 出版年:2013
  • 出版时间:August 2013
  • 年:2013
  • 卷:69
  • 期:8
  • 页码:2595-2608
  • 全文大小:517KB
  • 参考文献:1. Bai JH, Deng W, Wang QG, Ding QW (2007) Seasonal dynamics of carbon, nitrogen and phosphorous in soil profiles from an inland salt marsh. J Lake Sci 19(5):599-03
    2. Braekke FH (1990) Nutrient accumulation and role of atmospheric deposition in coniferous stands. Forest Ecol Manag 30(1-):351-59 CrossRef
    3. Bragato C, Brix H, Malagoli M (2006) Accumulation of nutrients and heavy metals in / Phragmites australis (Cav.) Trin. ex Steudel and / Bolboschoenus maritimus (L.) Palla in a constructed wetland of the Venice lagoon watershed. Environ Pollut 144:967-75 CrossRef
    4. Bulletin of Shandong Oceanic Environmental Quality (2009) http://www.soa.gov.cn/soa/hygb/yhgb/nine/webinfo/2010/06/1281687829218830.htm
    5. Chen LZ, Lindley DK (1983) Nutrient elements cycling in / Pteridium aquilinum grassland ecosystem of Hampsfe, England. Acta Ecol Sin 25(1):67-4
    6. Coelho JP, Flindt MR, Jensen HS, Lillebo AI, Pardal MA (2004) Phosphorus speciation and availability in intertidal sediments of a temperate estuary: relation to eutrophication and annual P-fluxes. Estuar Coast Shelf S 61:583-90 CrossRef
    7. Compton JS, Mallinson DJ, Glenn CR, Filippelli G, Follmi K, Shields G, Zanin Y (2000). Variations in the global phosphorus cycle. In: Glenn CR (ed) Marine authigenesis: from global to microbial society of sedimentary geology, Special Publication Number, 66:22-3
    8. Cui BS, Yang QC, Yang ZF, Zhang KJ (2009) Evaluating the ecological performance of wetland restoration in the Yellow River Delta, China. Ecol Eng 35:1090-103 CrossRef
    9. Dahlman RC, Kucera CL (1965) Root productivity and turnover in native prairie. Ecology 46:84-9 CrossRef
    10. Davis SM (1991) Growth, decomposition, and nutrient retention of / Cladium jamaicense Crantz and / Typha domingensis Pers. in the Florida Everglades. Aquat Bot 40(3):203-24
    11. Dunne EJ, Smith J, Perkins DB, Clark MW, Jawitz JW, Reddy KR (2007) Phosphorus storages in historically isolated wetland ecosystems and surrounding pasture uplands. Ecol Eng 31:16-8 CrossRef
    12. Gu FT (1998) Research in exploiting the green series of edibles- / Suaeda salsa. J Binzhou Edu Coll 5:43-8
    13. Han N, Shao Q, Lu CM, Wang BS (2005) The leaf tonoplast V-H+-ATPase activity of a C3 halophyte / Suaeda salsa is enhanced by salt stress n a Ca-dependent mode. J Plant Physiol 162:267-74 CrossRef
    14. He CQ, Zhao KY (2001) The accumulation, allocation and biological cycle of the nutrient elements in / Carex lasiocarpa wetland. Acta Ecol Sin 21(12):2074-080
    15. He HB, Li Y (2008) Study on measures of biomass allocation of two desert halophyte species under drought and salt stress. Arid Zone Res 25(2):242-47 CrossRef
    16. Hinsinger P (2001) Bioavailability of soil inorganic P in the rhizosphere as affected by root-induced chemical changes: a review. Plant Soil 237:173-95 CrossRef
    17. Hogan DM, Jordan TE, Walbridge MR (2004) Phosphorus retention and soil organic carbon in restored and natural freshwater wetlands. Wetlands 24:573-85 CrossRef
    18. Jiménez-Cárceles FJ, álvarez-Rogel J (2008) Phosphorus fractionation and distribution in salt marsh soils affected by mine waste and eutrophicated water: a case study in SE Spain. Geoderma 144:299-09 CrossRef
    19. Koerselman W, Meuleman AFM (1996) The vegetation N:P ratio: a new model tool to detect the nature of nutrient limitation. J Appl Ecol 33:1441-450 CrossRef
    20. Li YS, Redmann RE (1992) Nitrogen budget of / Agropyron dasystachyum in Canadian mixed prairie. Am Midl Nat 128:61-1 CrossRef
    21. Li YZ, Wang QS, Zhong XL, Ren N (2003) N internal cycling in / Leymus chinensis grassland vegetation-soil system. Acta Phytoecol Sin 27(2):177-82
    22. Lin P (2001) A review on the mangrove research in China. J. Xiamen Univ (Nat Sci) 40(2):592-03
    23. Liu JS, Li XH (2008) Sulfur cycle in the typical meadow / Calamagrostis angustifolia wetland ecosystem in the Sanjiang Plain, Northeast China. J Environ Sci 20:470-75 CrossRef
    24. Liu CE, Yang YX (2008) Characteristics of N, P and K cycling in / Phragmites australis wetland ecosystem in Jiuduansha shoal of Shanghai. Chin J Appl Ecol 27(3):418-24
    25. Liu JS, Sun XL, Yu JB (2000) Nitrogen content variation in litters of / Deyeuxia angustifolia and / Carex lasiocarpa in Sanjiang Plain. Chin J Appl Ecol 11(6):898-02
    26. Liu JS, Yu JB (2005) Element cycling in the dominant plant community in the Alpine tundra zone of Changbai Mountains, China. J Environ Sci 17(3):521-25
    27. Liu Y, Ding TL, Wang BS (2006) Study on the leaf succulence of / Sueada salsa under different natural saline environments. J Shandong Norm Univ (Nat Sci) 21(2):102-04
    28. Lu JL (2003) Plant nutrient. China Agricultural University Press, Beijing, pp 35-8
    29. Mistch WJ, Gosselin JG (2000) Wetlands. Van Nostrand Reinhold Company Inc, New York
    30. Mou XJ (2010) Study on the nitrogen biological cycling characteristics and cycling model of tidal wetland ecosystem in Yellow River estuary. Master degree dissertation, Yantai Institute of Coastal Zone Research, Chinese Academy of Sciences, Yantai
    31. Mou XJ, Sun ZG, Wang LL, Dong HF (2010) Characteristics of nitrogen accumulation and allocation of Suaeda salsa in different growth conditions of intertidal zone in Yellow River estuary. Wetland Sci 8(1):57-6
    32. Newman JM, Lynch T (2001) The Everglades nutrient removal project test cells: STA optimization—status of the research at the north site. Water Sci Technol 44:117-22
    33. Niedermeier A, Robinson JS (2009) Phosphorus dynamics in the ditch system of a restored peat wetland. Agr Ecosyst Environ 131:161-69 CrossRef
    34. Nielsen T, Andersen F? (2003) Phosphorus dynamics during decomposition of mangrove ( / Rhizophora apiculata) leaves in sediments. J Exp Mar Biol Ecol 293:73-8 CrossRef
    35. Olson JS (1963) Energy storage and the balance of products and decomposers in ecological systems. Ecology 44(2):322-31 CrossRef
    36. Qin SJ (2008) Study on the phosphorus transference and transformation process of / Calamagrostis angustifolia wetland in the Sanjian Plain. Doctor degree dissertation, Northeast Institute of Geography and Agroecology, Chinese Academy of Sciences, Changchun
    37. Qin SJ, Liu JS, Sun ZG (2006a) Dynamics of phosphorus and biomass accumulation of / Calamagrostis angustifolia in Sanjiang Plain. Chin J Appl Ecol 25(6):646-51
    38. Qin SJ, Liu JS, Wang GP (2006b) Mechanism of phosphorus availability changing in soil. Chin J Soil Sci 37(5):1012-016
    39. Qin SJ, Liu JS, Wang GP, Zhou WM (2007) Phosphorus fractions under different land uses in Sanjiang Plain. Environ Sci 28(12):2777-782
    40. Qu FZ, Yu JB, Meng L, Xu G (2010) Resin-P and its distribution profile in the / Suaeda salsa community soil in the Yellow River Delta coastal wetland. J Soil Water Conserv 24(6):150-52
    41. Rawat JS, Banerjee SP (1998) The influence of salinity on growth, biomass production and photosynthesis of / Eucalyptus camaldulensis Dehnh. and / Dalbergia sissoo Roxb. seedlings. Plant Soil 205:163-69 CrossRef
    42. Reuss JO, Innis GS (1977) A grassland nitrogen flow simulation model. Ecology 58:379-88 CrossRef
    43. Ruan Y, Liu Y, Wang BS (2008) Study on the pigment accumulation and characteristics of photosynthesis of / Suaeda salsa under different natural saline environments. J Shandong Norm Univ (Nat Sci) 23(1):115-17
    44. Stribling JM, Cornwell JC (2001) Nitrogen, phosphorus, and sulfur dynamics in a low salinity marsh system dominated by / Spartina alterniflora. Wetlands 21(4):629-38 CrossRef
    45. Sun ZG, Liu JS (2007) Nitrogen cycling of atmosphere-plant-soil system in the / Calamagrostis angustifolia wetland in the Sanjiang Plain, Northeast China. J Environ Sci 19:986-95 CrossRef
    46. Sun ZG, Liu JS (2008) Distribution and fate of anthropogenic nitrogen in the / Calamagrostis angustifolia wetland ecosystem of Sanjiang Plain, Northeast China. J Integr Plant Biol 50(4):402-14 CrossRef
    47. Sun ZG, Qin SJ, Liu JS, Wang JD (2007) Biomass structure and nitrogen, phosphorus nutrient of / Calamagrostis angustifolia populations in different communities of Sanjiang Plain, Northeast China. Fornt For China 2(4):366-75 CrossRef
    48. Tessier JT, Raynal DJ (2003) Use of nitrogen to phosphorus ratios in plant tissue as an indicator of nutrient limitation and nitrogen saturation. J Appl Ecol 40:523-34 CrossRef
    49. The Committee of Agro-chemistry of the Chinese Society of Soil Science (1983) The conventional analysis methods in soil agro-chemistry. Science Press, Beijing
    50. Tian HQ, Chen GS, Zhang C, Melillo JM, Hall C (2010) Pattern and variation of C:N:P ratios in China’s soils: a synthesis of observational data. Biogeochemistry 98:139-51 CrossRef
    51. Tian JY, Wang XF, Cai XJ (2005) Protection and restoration technique of wetland ecosystem in Yellow River Delta. China Ocean University Press, Qingdao
    52. Walbridge MR (2000) Phosphorus biogeochemistry. Ecology 81:1474-475 CrossRef
    53. Wallance A, Romney EM, Kleinkopf GE (1978) Uptake of mineral forms of nitrogen by desert plants. In: West NE, Skujins JJ (eds) Nitrogen in desert ecosystems. Hutchinson and Ross, Dowden, 130-51
    54. Wang GP, Liu JS (2002) Overview on wetland biogeochemistry. J Soil Water Conserv 16(4):144-48
    55. Wang CQ, Zhao JQ, Chen M, Wang BS (2006) Identification of betacyanin and effects of environmental factors on its accumulation in halophyte / Suaeda salsa. J Plant Physiol Mol Biol 32:195-01
    56. Wang LL, Hu JM, Song CC, Yang T (2008) Influences of water gradients on the aboveground biomass of a typical wetland plant ( / Calamagrostis angustifolia) in the Sanjiang Plain. Acta Pratacul Sin 17(4):19-5
    57. Wang Q, Sun JX, An Y (2009) The effect of the population properties and stress-tolerance physiological characteristics of / Zoysia grass under water stresses. Acta Pratacul Sin 18(2):33-8
    58. Wei J, Wu G, Wang H, Hao YJ, Shang WY (2005) Phosphorus and sulphur bio-cycling in alpine tundra ecosystem of Changbai Mountains. Chin J Appl Ecol 16(7):1230-234
    59. Wu G, Wei J, Deng HB, Zhao JZ (2006) Nutrient cycling in an Alpine tundra ecosystem on Changbai Mountain, Northeast China. Appl Soil Ecol 32(2):2087-092 CrossRef
    60. Xiao R, Bai JH, Zhang HG, Gao HF, Liu XH, Andreas W (2011) Changes of P, Ca, Al and Fe contents in fringe marshes along a pedogenic chronosequence in the Pearl River estuary, South China. Cont Shelf Res 31(6):739-47 CrossRef
    61. Xiao R, Bai JH, Gao HF, Huang LB, Deng W (2012) Spatial distribution of phosphorus in marsh soils of a typical land/inland water ecotone along a hydrological gradient. Catena 98:96-03 CrossRef
    62. Xu XG, Guo HH, Chen XL, Lin HP, Du QL (2002) A multi-scale study on land use and land cover quality change: the case of the Yellow River Delta in China. GeoJournal 56(3):177-83 CrossRef
    63. Yang JS, Liu JS, Yu JB, Wang JD, Li XH, Sun ZG (2006) Decomposition and nutrient dynamics of marsh litter in the Sanjiang Plain, Northeast China. Acta Ecol Sin 26(5):1297-302 CrossRef
    64. Yang YX, Liu CE, Yang Y (2009a) Characteristics of N, P and K cycling in / Spartina alterniflora wetland ecosystem in Jiuduansha shoal of Yangtze River estuary. Chin J Appl Ecol 28(2):223-30
    65. Yang YX, Liu CE, Yang Y (2009b) Characteristics of N, P and K cycling in / Scirpus mariqueter wetland ecosystem at Jiuduansha shoal of Yangtze River estuary. Chin J Appl Ecol 28(10):1977-985
    66. Zhang C, Tian HQ, Liu J, Wang S, Liu M, Pan S, Shi X (2005). Pools and distributions of soil phosphorus in China. Global Biogeochem Cy 19:GB1020
    67. Zhang J, Li M, Liu S, Liu YJ, Zhang LQ, Cao Q, Sun DZ (2011) Seasonal variations and bioavailability of inorganic phosphorus in soils of Yeyahu Wetland in Beijing, China. Int J Sediment Res 26(2):181-92 CrossRef
  • 作者单位:Zhigao Sun (1)
    Xiaojie Mou (1)
    Hanqin Tian (2)
    Hongli Song (1)
    Huanhuan Jiang (1)
    Jinyong Zhao (3)
    Wanlong Sun (1)
    Wenguang Sun (1)

    1. Key Laboratory of Coastal Zone Environmental Processes, Yantai Institute of Coastal Zone Research (YIC), Chinese Academy of Sciences (CAS); Shandong Provincial Key Laboratory of Coastal Zone Environmental Processes, YICCAS, Yantai, 264003, Shandong, People’s Republic of China
    2. International Center for Climate and Global Change Research, School of Forestry and Wildlife Sciences, Auburn University, Auburn, AL, 36849, USA
    3. China Institute of Water Resources and Hydropower Research, Beijing, 100038, People’s Republic of China
文摘
Much uncertainty exists in the phosphorus (P) cycle in the marshes of the intertidal zone. This study explored the P cycling in the two Suaeda salsa marshes [middle S. salsa marsh (MSM) and low S. salsa marsh (LSM)] of the Yellow River estuary during April 2008 to November 2009. Results showed seasonal fluctuations and vertical distributions of P in different S. salsa marsh soils, and variations in P content in different parts of plants due to water and salinity status. The N/P ratios of the different S. salsa were 9.87?±?1.23 and 15.73?±?1.77, respectively, indicating that plant growth in MSM was limited by N, while that in LSM was limited by both N and P. The S. salsa litter in MSM released P to the environment throughout the year, while that in LSM immobilized P from the environment at all times. The P absorption coefficients of S. salsa in MSM and LSM were very low (0.0010 and 0.0001, respectively), while the biological cycle coefficients were high (0.739 and 0.812, respectively). The P turnovers among compartments of MSM and LSM showed that the uptake amounts of roots were 0.4275 and 0.0469?g?m??year? and the values of aboveground parts were 1.1702 and 0.1833?g?m??year?, the re-translocation quantities from aboveground parts to roots were 0.8544 and 0.1452?g?m??year?, the translocation amounts from roots to soil were 0.0137 and 0.0012?g?m??year?, the translocation quantities from aboveground living bodies to litter were 0.3157 and 0.0381?g?m??year?, and the annual return quantities from litter to soil were less than 0.0626 and ?.0728?g?m??year? (minus represented immobilization), respectively. P was an important limiting factor in S. salsa marshes, especially in LSM. S. salsa was seemingly well adapted to the low-nutrient condition and the vulnerable habitat, and the nutrient enrichment due to the import of N and P from the Yellow River estuary would be a potential threat to the S. salsa marshes.
NGLC 2004-2010.National Geological Library of China All Rights Reserved.
Add:29 Xueyuan Rd,Haidian District,Beijing,PRC. Mail Add: 8324 mailbox 100083
For exchange or info please contact us via email.