Plant & Forest
Amara E, Heiskanen J, Aynekulu E, Pellikka PKE. 2019. Relationship between carbon stocks and tree species diversity in a humid Guinean savanna landscape in northern Sierra Leone. Southern Forests: A Journal of Forest Science 81:235-245.
10.2989/20702620.2018.1555947Augustin C, Cihacek LJ. 2016. Relationships between soil carbon and soil texture in the northern great plains. Soil Science 181:386-392.
10.1097/SS.0000000000000173Baul TK, Chakraborty A, Nandi R, Mohiuddin M, Kilpeläien A, Sultana T. 2021. Effects of tree species diversity and stand structure on carbon stocks of homestead forests in Maheshkhali Island, Southern Bangladesh. Carbon Balance and Management 16:11.
10.1186/s13021-021-00175-633909182PMC8080351Calleja-Cabrera J, Boter M, Oñate-Sánchez L, Pernas M. 2020. Root growth adaptation to climate change in crops. Frontiers in Plant Science 11:544.
10.3389/fpls.2020.0054432457782PMC7227386Cambou A, Shaw RK, Huot H, Vidal-Beaudet L, Hunault G, Cannavo P, Nold F, Schwartz C. 2018. Estimation of soil organic carbon stocks of two cities, New York City and Paris. Science of The Total Environment 644:452-464.
10.1016/j.scitotenv.2018.06.32229981995Chen X, Li BL. 2003. Change in soil carbon and nutrient storage after human disturbance of a primary Korean pine forest in Northeast China. Forest Ecology and Management 186:197-206.
10.1016/S0378-1127(03)00258-5Chettri R, Tamang M, Sarkar BC, Shukla G, Vineeta, Debnath MK, Nath AJ, Bhat JA, Chakravarty S. 2023. Species richness, stand structure and carbon storage under an age chronosequence in Tectona grandis plantation at agricultural landscape of Indian Eastern Himalayan Foothill. Tropical Ecology 64:681-697.
10.1007/s42965-023-00295-9Chun J, Kim CK, Kang W, Park H, Kim G, Lee WK. 2019. Sustainable management of carbon sequestration service in areas with high development pressure: Considering land use changes and carbon costs. Sustainability 11:5116.
10.3390/su11185116Culmess H, Leuschner C, Moser G, Pitopang R. 2010. Forest aboveground biomass along an elevational transect in Sulawesi, Indonesia, and the role of Fagaceae in tropical montane rain forests. Journal of Biogeography 37:960-974.
10.1111/j.1365-2699.2009.02269.xDale GB. 1998. Forest plant diversity at local and landscape scales in the Cascade Mountains of southwestern Washington. Forest Ecology and Management 109:323-341.
10.1016/S0378-1127(98)00266-7GIR (Greenhouse Gas Inventory and Research Center). 2023. 2022 National Greenhouse Gas Inventory Report of Korea. GIR, Osong, Korea. [in Korean]
Girma A, Soromessa T, Bekele T. 2014. Forest carbon stocks in woody plants of Mount Zequalla Monastery and it's variation along altitudinal gradient: Implication of managing forests for climate change mitigation. Science, Technology and Arts Research Journal 3:132-140.
10.4314/star.v3i2.17Homeier J, Breckle SW, Günter S, Rollenbeck RT, Leuschner C. 2010. Tree diversity, forest structure and productivity along altitudinal and topographical gradients in a species-rich Ecuadorian montane rain forest. Biotropica 42:140-148.
10.1111/j.1744-7429.2009.00547.xIPCC (Intergovernmental Panel on Climate Change). 2006. IPCC Guidelines for National Greenhouse Gas Inventories. Volume 4: Agriculture, forestry and other land use. Institute for Global Environmental Strategies (IGES), Hayama, Japan.
Jang JH, Yi JS, Jeong JS, Song TY, Lee K, Suh SU, Lee J. 2014. A study of estimation of forest ecosystem carbon storage in Gyeryongsan National Park, Korea. Korean Journal of Ecology and Environment 47:319-327. [in Korean]
10.11614/KSL.2014.47.4.319Jeong JH, Koo KS, Lee CH, Kim CS. 2002. Physico-chemical properties of Korean forest soils by regions. Journal of Korean Forest Society 91:694-700. [in Korean]
Kalra YP, Maynard DG. 1991. Methods Manual for Forest Soil and Plant Analysis. Information Report NOR-X-319. Norther Forest Centre, Edmonton, Alberta, Canada.
Kang HM, Kim DH, Park SG. 2020. Characteristics of Quercus mongolica dominant community on the ridge of the Nakdon-Jeongmaek -Focusing on the Baekbyeongsan, Chilbosan, Baegamsan, Unjusan, Goheonsan, Gudeoksan-. Korean Journal of Environment and Ecology 34:318-333. [in Korean]
10.13047/KJEE.2020.34.4.318Kasper J, Weigel R, Walentowski H, Gröning A, Petritan AM, Leuschner C. 2021. Climate warming-induced replacement of mesic beech by thermophilic oak forests will reduce the carbon storage potential in aboveground biomass and soil. Annals of Forest Science 78:89.
10.1007/s13595-021-01081-0KFS (Korea Forest Service). 2016. Analysis and Monitoring Study of National Forest Inventory. KFS, Daejeon, Korea. [in Korean]
Kim DH. 2017. A study on the composition characteristics of Q. mongolica communities in the Baekdudaegan mountains. Ph.D. dissertation, Dongguk Univ., Seoul, Korea. [in Korean]
Kim JW, Manyko YI. 1994. Syntaxonomical and synchorological characteristics of the cool-temperate mixed forest in the southern Sikhote Alin, Russian Far East. The Korean Journal of Ecology 17:391-413.
Kim SG, Kwon B, Son Y, Yi MJ. 2018. Carbon storage in an age-sequence of temperate Quercus mongolica stands in central Korea. Journal of Forest and Environmental Science. 34:472-480.
10.7747/JFES.2018.34.6.472Kim SG. 2019. Thinning, age and density impacts on tree and soil carbon storage in Quercus mongolica and Q. variabills forest in central Korea. Ph.D. dissertation, Kangwon National Univ., Chuncheon, Korea. [in Korean]
Kwon KC, Han SA, Lee DK, Jung IK, Seo YJ, Shin KT, Jeon CS. 2022. Site characteristics and stand structure of Quercus mongolica forests in the Republic of Korea. Journal of Korean Society of Forest Science 111:100-107. [in Korean]
10.14578/jkfs.2022.111.1.100Kwon KC, Lee DK. 2006. Energy content of Quercus mongolica stands in Korea with respect to latitude and altitude. Journal of Korean Forest Society 95:299-308. [in Korean]
Kwon KC. 2006. Biomass, carbon storage, and photosynthetic efficiency of Quercus mongolica stands in Korea with respect to latitude, altitude, and aspect. Ph.D. dissertation, Seoul National Univ., Seoul, Korea. [in Korean]
Lee HJ, Lee JS, Byun DW. 1994. Community classification and vegetation pattern of Quercus mongolica forest in Mt. Myongji. The Korean Journal of Ecology 17:185-201. [in Korean]
Lee NY. 2012. Estimation of carbon storage in three cool-temperate broad-leaved deciduous forests at Jirisan National Park, Korea. Korean Journal of Environmental Biology 30:121-127. [in Korean]
Lee SJ, Yim JS, Son YM, Son Y, Kim R. 2018. Estimation of forest carbon stocks for national greenhouse gas inventory reporting in South Korea. Forests 9:625.
10.3390/f9100625Lee SK, Son Y, Noh NJ, Heo SJ, Yoon TK, Razak SA, Lee WK. 2009. Carbon storage of natural pine and oak pure and mixed forests in Hoengseong, Kangwon. Journal of Korean Forest Society 98:772-779. [in Korean]
Lee ST, Chung SH, Kim C. 2022. Carbon stocks in tree biomass and soils of Quercus acutissima, Q. Mongolica, Q. Serrata, and Q. Variabilis stands. Journal of Korean Society of Forest Science 111:365-373. [in Korean]
10.14578/jkfs.2022.111.3.365Lee T, Kim S, Shin Y, Jung Y, Lim KJ, Yang JE, Jang WS. 2019. Development of soil organic carbon storage estimation model using soil characteristics. Journal of the Korean Society of Agricultural Engineers 61:1-8. [in Korean]
10.5389/KSAE.2019.61.6.001Li P, Wang Q, Endo T, Zhao X, Kakubari Y. 2010. Soil organic carbon stock is closely related to aboveground vegetation properties in cold-temperate mountainous forests. Geoderma 154:407-415.
10.1016/j.geoderma.2009.11.023Matus FJ. 2021. Fine silt and clay content is the main factor defining maximal C and N accumulations in soils: A meta-analysis. Scientific Reports 11:6438.
10.1038/s41598-021-84821-633742022PMC7979709Merabtene MD, Faraoun F, Mlih R, Djellouli R, Latreche A, Bol R. 2021. Forest soil organic carbon stocks of Tessala Mount in north-west Algeria-preliminary estimates. Frontiers in Environmental Science 8:520284.
10.3389/fenvs.2020.520284NIFoS (National Institute of Forest Science). 2014. Carbon Emission Factors and Biomass Allometric Equations by Species in Korea. NIFoS, Seoul, Korea. [in Korean]
O'Neill KP, Amacher MC, Perry CH. 2005. Soils as an Indicator of Forest Health: A Guide to the Collection, Analysis, and Interpretation of Soil Indicator Data in the Forest Inventory and Analysis Program. General Technical Report NC-258. U.S. Department of Agriculture, Forest Service, North Central Research Station, St. Paul, MN, USA.
10.2737/NC-GTR-258Oren R, Ellsworth DS, Johnsen KH, Phillips N, Ewers BE, Maier C, Schäfer KV, McCarthy H, Hendrey G, McNulty SG, et al. 2001. Soil fertility limits carbon sequestration by forest ecosystems in a CO2-enriched atmosphere. Nature 411:469-472.
10.1038/3507806411373677Park IH, Seo YK, Choi YC. 2003. Forest structure in relation to slope aspect and altitude in valley forests at Baraebong, Jirisan National Park. Korean Journal of Environment and Ecology 16:449-456. [in Korean]
Peichl M, Arain MA. 2006. Above- and belowground ecosystem biomass and carbon pools in an age-sequence of temperate pine plantation forests. Agricultural and Forest Meteorology 140:51-63.
10.1016/j.agrformet.2006.08.004Penn CJ, Camberato JJ. 2019. A critical review on soil chemical processes that control how soil pH affects phosphorus availability to plants. Agriculture 9:120.
10.3390/agriculture9060120Pérez CA, Carmona MR, Aravena JC, Aarmesto JJ. 2004. Successional changes in soil nitrogen availability, non-symbiotic nitrogen fixation and carbon/nitrogen ratios in southern Chilean forest ecosystems. Oecologia 140:617-625.
10.1007/s00442-004-1627-y15221437Poeplau C, Vos C, Don A. 2017. Soil organic carbon stocks are systematically overestimated by misuse of the parameters bulk density and rock fragment content. Soil 3:61-66.
10.5194/soil-3-61-2017Pregitzer KS, Euskirchen ES. 2004. Carbon cycling and storage in world forests: Biome patterns related to forest age. Global Change Biology 10:2052-2077.
10.1111/j.1365-2486.2004.00866.xRothstein DE, Yermakov Z, Buell AL. 2004. Loss and recovery of ecosystem carbon pools following stand-replacing wildfire in Michigan jack pine forests. Canadian Journal of Forest Research 34:1908-1918.
10.1139/x04-063Sah JP, Ross MS, Koptur S, Snyder JR. 2004. Estimating aboveground biomass of broadleaved woody plants in the understory of Florida Keys pine forests. Forest Ecology and Management 203:319-329.
10.1016/j.foreco.2004.07.059Sahoo UK, Tripathi OP, Nath AJ, Deb S, Das DJ, Gupta A, Devi NB, Charturvedi SS, Singh SL, Kumar A, et al. 2021. Quantifying tree diversity, carbon stocks, and sequestration potential for diverse land uses in Northeast India. Frontiers in Environmental Science 9:724950.
10.3389/fenvs.2021.724950Salinas-Melgoza MA, Skutsch M, Lovett JC. 2018. Predicting aboveground forest biomass with topographic variables in human-impacted tropical dry forest landscapes. Ecosphere 9:e02063.
10.1002/ecs2.2063Shin JW, Jeong SJ, Chang DY. 2023. Estimation of forest carbon stock in South Korea using machine learning with high-resolution remote sensing data. Atmosphere 33:61-72. [in Korean]
10.14191/Atmos.2023.33.1.061Shin MY, Lee SM, Lee DK. 2005. Forest management using growth and ecological characteristics by site types in the natural deciduous forest. Journal of Korean Forest Society 94:26-33. [in Korean]
Shin MY, Yim JS, Lee DK. 2001. A study on stand structure and competition status by site types in natural deciduous forest of Pyungchang, Kangwon-do. Journal of Korean Forest Society 90:295-305. [in Korean]
Smith JE, Heath LS. 2002. A Model of Forest Floor Carbon Mass for United States Forest Types. Research Paper NE-722. U.S. Department of Agriculture, Forest Service, Northeastern Research Station, Newtown Square, PA, USA.
10.2737/NE-RP-722Starr JL, Meisinger JJ, Parkin TB. 1995. Influence of sample size on chemical and physical soil measurements. Soil Science Society of America Journal 59:713-719.
10.2136/sssaj1995.03615995005900030012xTalukdar S, Singha P, Mahato S, Shahfahad, Pal S, Liou YA, Rahman A. 2020. Land-use land-cover classification by machine learning classifiers for satellite observations-A review. Remote Sensing 12:1135.
10.3390/rs12071135Wang N, Cheng J, Liu Y, Xu Q, Zhu C, Ling N, Guo J, Li R, Huang W, Guo S, et al. 2024. Relative importance of altitude shifts with plant and microbial diversity to soil multifunctionality in grasslands of north-western China. Plant and Soil.
10.1007/s11104-024-06641-7Wellbrock N, Grüneberg E, Riedel T, Polley H. 2017. Carbon stocks in tree biomass and soils of German forests. Central European Forestry Journal 63:105-112.
10.1515/forj-2017-0013Whittaker RH. 1965. Dominance and diversity in land plant communities: Numerical relations of species express the importance of competition in community function and evolution. Science 147:250-260.
10.1126/science.147.3655.25017788203Won HY, Oh KH, Pyo JH, Mun HT. 2012. Decay rate and nutrient dynamics during litter decomposition of Quercus acutissima and Quercus mysinaefolia. Korean Journal of Environment and Ecology 26:74-81. [in Korean]
Yue JW, Guan JH, Yan MJ, Zhang JG, Deng L, Li G, Du S. 2018. Biomass carbon density in natural oak forests with different climate conditions and stand ages in northwest China. Journal of Forest Research 23:354-362.
10.1080/13416979.2018.1536313- Publisher :Institute of Agricultural Science, Chungnam National University
- Publisher(Ko) :충남대학교 농업과학연구소
- Journal Title :Korean Journal of Agricultural Science
- Journal Title(Ko) :농업과학연구
- Volume : 51
- No :4
- Pages :413-427
- Received Date : 2024-07-15
- Revised Date : 2024-08-20
- Accepted Date : 2024-09-01
- DOI :https://doi.org/10.7744/kjoas.510401