Journal of Ecology and Environment

The Ecological Society of Korea (한국생태학회)
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Litter Production and Nutrient Contents of Litterfall in Oak and Pine Forests at Mt. Worak National Park

  • Published : 2007.02.28
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Abstract

Litter production, nutrient contents of each component of litterfall and amount of nutrients returned to forest floor via litterfall were investigated from May 2005 through April 2006 in Quercus mongolica, Quercus variabilis and Pinus densiflora forests at Mt. Worak National Park. Total amount of litterfall during one year in Q. mongolica, Q. variabilis and P. densiflora forests was 542.7, 459.2 and $306.9\;g\;m^{-2}\;yr^{-1}$, respectively. Of the total litterfall, leaf litter, branch and bark, reproductive organ and the others occupied 50.3%, 22.7%, 10.1 % and 16.9% in Q. mongolica forest, 81.9%, 7.2%, 3.1% and 7.9% in Q. variabilis forest, 57.4%, 12.8%, 5.6% and 24.1 % in P. densiflora forest, respectively. Nutrients concentrations in oak litterfall were higher than those in needle litter. N, P, K, Ca and Mg concentration in leaf litterfall were 13.8, 1.1, 7.2, 4.2 and 1.3 mg/g for Q. mongolica forest, 10.5, 0.7, 3.2, 3.7 and 1.6 mg/g for Q. variabilis forest, 5.3, 0.4, 1.2, 2.8 and 0.6mg/g for P. densiflora forest, respectively. The amount of annual input of N, P, K, Ca and Mg to the forest floor via litterfall was 43.36, 2.89, 21.38, 23.31 and $5.62\;kg\;ha^{-1}\;yr^{-1}$ for Q. mongolica forest, 32.28, 2.01, 10.23, 20.29 and $7.78\;kg\;ha^{-1}\;yr^{-1}$ for Q. variabilis forest, 15.80, 1.04, 3.99, 9.70 and $2.10\;kg\;ha^{-1}\;yr^{-1}$ for P. densiflora forest, respectively.

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References

  1. Allen SE, Grimshaw HM, Parkinson JA, Quarmby C. 1974. Chemical analysis of ecological materials. Blackwell. Oxford
  2. Baker TT III, Lockaby BG, Conner WH, Meier CE, Stanturf JA, Burke MK. 2001. Leaf litter decomposition and nutrient dynamics in four southern forested floodplain communities. Soil Sci Soc Amer J 65: 1334-1347 https://doi.org/10.2136/sssaj2001.6541334x
  3. Barbour MG, Burk JH, Pitts WD. 1987. Terrestrial plant ecology. The Benjamin/Cummings, Menlo Park, California. p. 634
  4. Bray JR, Gorham E. 1964. Litter production in forests of the world. In: Advances in Ecological Research. Vol. 2. Graff JB (ed). Academic Press, New York. pp. 101-157
  5. Choi HJ, Jeon IY, Shin C-H, Mun HT. 2006. Soil properties of Quercus variabilis forest on Youngha valley in Mt. Worak National Park. J Ecol Field Biol 29: 439-443 https://doi.org/10.5141/JEFB.2006.29.5.439
  6. Daubenmire RF. 1974. Plant and environment. 3rd ed., New York, Wiley
  7. Gholz HL, Perry CS, Cropper WP, Hendry LC. 1985. Litterfall, decomposition, and nitrogen and phosphorus dynamics in a chronosequence of Slash pine (Pinus elliottii) plantations. Forest Sci 31: 463-478
  8. Kim C. 2006. Soil carbon cycling and soil $CO_{2}$ efflux in a red pine (Pinus densiflora) stand. J Ecol Field Biol 29: 23-27 https://doi.org/10.5141/JEFB.2006.29.1.023
  9. Kim HS. 2007. Biomass production and nutrients distribution of Quercus mongolica forest at Mt. Worak National Park. (MS thesis). Kongju National University
  10. Kimmins J.P. 1987. Forest ecology. Macmillan Publishing Company, New York
  11. Mun HT, Joo HT. 1994. Litter production and decomposition in the Quercus acutissima and Pinus rigida forests. Korean J Ecol 17: 345-353
  12. Mun HT, Kim JH. 1992. Litterfall, decomposition, and nutrient dynamics of litter in red pine (Pinus densiflora) and Chines thuja (Thuja orientalis) stands in the limestone area. Korean J Ecol 15: 147-155
  13. Reich JW, Nadelhoffer KJ. 1989. Belowground carbon allocation in forest ecosystems: global trends. Ecology 70: 1346-1354 https://doi.org/10.2307/1938194
  14. Wiegert, RG, Monk CD. 1972. Litter production and energy accumulation in three plantations of longleaf pine (Pinus palustris Mill.). Ecology 53: 949-953 https://doi.org/10.2307/1934314
  15. Yi MJ, Son Y, Jin HO, Park I-H, Kim DY, Kim YS, Shin DM. 2005. Belowground carbon allocation of natural Quercus mongolica forests estimated from litterfall and soil respiration measurements. Korean J Agri For Meteorology 7: 227-234