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Carbon storage, Litterfall and Soil $CO_2$ Efflux of a Larch(Larix leptolepis) Stand  

Kim, Choon-Sig (Department of Forest Resources, Jinju National University)
Publication Information
Animal cells and systems / v.10, no.4, 2006 , pp. 191-196 More about this Journal
Abstract
This study was carried out to evaluate soil carbon cycling of a 36-year-old larch (Larix leptolepis) stand in Korea. The aboveground and soil organic carbon storage, litterfall, and soil respiration rates were measured over twoyear periods. The estimated aboveground biomass carbon storage and increment were 4220 gC $m^{-2}$ and 150 gC $m^{-2}\;yr^{-1}$, respectively. Mean organic carbon inputs by needle and total litterfall were 118 gC $m^{-2}\;yr^{-1}$ and 168 gC $m^{-2}\;yr^{-1}$, respectively. The aboveground carbon increment of the stand was similar to the annual input of carbon from total litterfall. The soil respiration rates correlated exponentially with the soil temperature at a depth of 20 cm ($R^2$ = 0.86). In addition, the exponential regression equation indicated a relatively strong positive relationship between the soil respiration rates and soil temperature, while there was no significant relationship between the soil respiration rates and the soil moisture content. The annual mean and total soil respiration rates were 0.40 g $CO_2\;m^{-2} h^{-1}$ and 3010 g $CO_2\;m^{-2}\;yr^{-1}$ over the two-year study period, respectively.
Keywords
Carbon cycling; carbon dynamics; soil carbon; soil respiration;
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1 Raich JW and Schlesinger WH (1992) The global carbon dioxide flux in soil respiration and its relationship to vegetation and climate. Tellus 44 B: 81-99
2 Raich JW (1998) Aboveground productivity and soil respiration in three Hawaiian rain forests. For Ecol Manage 107: 309-318   DOI   ScienceOn
3 Rey A, Pegoraro E, Tedeschi V, De Parri I, Jarvis PO; and Valentini R (2002) Annual variation in soil respiration and its components in a coppice oak forest in Centrol Italy. Global Change BioI. 8: 851-866   DOI   ScienceOn
4 Pypker TG and Fredeen AL (2003) Below ground $CO_2$ efflux from cut blocks of varying ages in sub-boreal British Columbia. For Ecol Manage 172: 249-259   DOI   ScienceOn
5 Melillo JM, McGuire AD, Kicklighter DW, Moore B, Vorosmarty CJ, and Schloss AL (1993) Global climate change and terrestrial net primary production. Nature 363: 234-240   DOI   ScienceOn
6 McPherson EG and Simpson JR (1999) Carbon Dioxide Reduction through Urban Forestry: Guideline for Professional and Volunteer Tree Planters. USDA-USFS General Technical Report PSW-GTR-171
7 Nakane K (1995) Soil carbon cycling in a Japanese cedar (Cryptomeria japonica) plantation. For Ecol Manage 72: 185-187   DOI   ScienceOn
8 Ohashi M, Gyokusen K, and Saito A (1999) Measurement of carbon dioxide evolution from a Japanese ceder (Cryptomeria japonica D. Don) forest floor using an open-flow chamber method. For Ecol Manage 123: 105-114   DOI   ScienceOn
9 Laporte MF, Duchesne LC, and Morrison IK (2003) Effect of clearcutting, selection cutting, shelterwood cutting and micro sites on soil surface $CO_2$ efflux in a tolerant hardwood ecosystem of northern Ontario. For Ecol Manage 174: 565-575   DOI   ScienceOn
10 Lee KH and Jose S (2003) Soil respiration, fine root respiration, fme root production, and microbial biomass in cottonwood and loblolly plantations along a nitrogen fertilization gradient. For Ecol Manage 185: 263-273   DOI   ScienceOn
11 Kim KH, Kim YS, Kim C, Beck US, Son YM, Song JH, Lee KS, Lee KH, Lee JK, Jeong YK, Jeong YJ, and Joo LO (1998) Forest Management for Mitigation of Greenhouse Gas Emissions. Research Report of Korea Forest Research Institute 143. (In Korean)
12 Kim C and Jeong JH (2001) Change of aboveground carbon storage in a Pinus rigida stand in Gwangnung, Gyunggi-do, Korea. J Kor For Soc 90: 774-780. (in Korean with English summary)
13 Kim C (2004) Effects of stand density on carbon dynamics in a larch (Larix leptolepis) plantation. J Kor For Soc 93: 355-362
14 Kim C and Cho HS (2004) Quantitative comparisons of soil carbon and nutrient storage in Larix leptolepis, Pinus densiflora and Pinus rigitaeda plantations. Kor J Ecol 27: 67-71   과학기술학회마을   DOI
15 Forest Administration (1994) Statistical Yearbook of Forestry. Korea Forest Administration. (In Korean)
16 Jeong JH, Kim C, and Lee WK (1998) Soil organic carbon content in forest soils of Korea. For Res Ins J For Sci 57: 178-183. (in Korean with English summary)
17 Johnson DW (1992) Effects offorest management and soil carbon storage. Water, Air, Soil Pollution 64: 83-120   DOI
18 Janssens lA, Sampson DA, Curiel-Yuste J, Carrara A, and Ceulemans R (2002) The carbon cost of fine root turnover in a Scot pine forest. For Ecol Manage 168: 231-240   DOI   ScienceOn
19 Hwang J (2004) Belowground Carbon Dynamics after Thinning, Liming and Litter Layer Treatments in Pinus rigida and Larix leptolepis Plantations. Ph.D. Dissertation. Korea University. 169 pp.
20 Ewel KC, Cropper Jr WP, and Gholz HL (1987) Soil $CO_2$ evolution in Florida slash pine plantations II. Importance of root respiration. Can J For Res 17: 330-333   DOI
21 Fox TR (2000) Sustained productivity in intensively managed forest plantations. For Ecol Manage 138: 187-202   DOI   ScienceOn
22 Davis MR, Allen RB, and Clinton PW (2003) Carbon storage along a stand development sequence in a New Zealand Nothofagus forest. For Ecol Manage 177: 313-321   DOI   ScienceOn
23 Davidson EA, Savage K, Bolstad P, Clark DA, Curtis PS, Ellsworth DS, Hanson PJ, Law BE, Luo Y, Pregitzer KS, Randolph JC, and Zak D (2002) Belowground carbon allocation in forest estimated from litterfall and IRGA-based soil respiration measurement. Agri For Metero 113: 39-51   DOI   ScienceOn
24 Bowden RD, Nadelhopffer KJ, Boone RD, Melillo JM, and Garrison JB (1993) Contributions of aboveground litter, belowground litter, and root respimtion to total soil respiration in a temperate mixed hardwood forest. Can J For Res 23: 1402-1407   DOI
25 Yi MJ (2003) Soil $CO_2$ evolution in Quercus variabilis and Q. mongolica forest in Chunchon, Kangwon Province. J Kor For Soc 92: 263-269. (in Korean with English summary)
26 Bmy JR and Gorham E (1964) Litter production in forests of the world. Adv Ecol Res 2:101-157   DOI
27 Borken W and Beese F (2005) Soil respimtion in pure and mixed stands of European beech and Norway spruce following removal of organic horizons. Can J For Res 35: 2756-2764   DOI   ScienceOn
28 Sulzman EW, Brant JB, Bowden RD, and Lajtha K (2005) Contribution of aboveground litter, belowground litter, and rhizosphere respiration to soil $CO_2$ efflux in an old growth coniferous forest. Biogeochemistry 73: 231-256   DOI
29 Watson RT, Novel IR, Bolin B, Ravindmnath NH, Verardo DJ, and Dokken DJ (2000) Land use, Land-use Change, and Forestry. Cambridge University Press
30 Wiseman PE and Seiler JR (2004) Soil $CO_2$ efflux across four age classes of plantation loblolly pine (Pinus taeda L.) on the Virginia Piedmont. For Ecol Manage 192: 297-311   DOI   ScienceOn
31 Son Y, Lee G, and Hong JY (1994) Soil carbon dioxide evolution in three deciduous tree plantations. Kor J Soil Sci Fert 27: 290-295
32 Son Y and Kim HW (1996) Soil respimtion in Pinus rigida and Larix leptolepis plantatrions. J Kor For Soc 85: 496-505
33 Soon YK and Abboud S (1991) A comparison of some methods for soil organic carbon determination. Comm Soil Sci Plant Anal 22: 934-954