• The Korean Journal of Ecology
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• v.26 no.4
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• pp.155-163
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• 2003

In order to analyze the succession process from a pine forest to an oak forest, the tree growth of Pinus densiflora and Quercus mongolica ssp. crispula was monitored in a permanent quadrat for 23 years. The measurements were carried out for the stem diameter (DBH) of Pinus densiflora between 1977 and 1999 and for the height of Quercus mongolica ssp. crispula saplings between 1998 and 2000. The floristic composition and the locations of the individual P. densiflora and Q. mongolica ssp. crispula trees and saplings in the quadrat were recorded. P densiflora and Q. mongolica ssp. crispula individuals were randomly distributed within the quadrat. The relative growth rates (RGR) of DBH in P. densiflora were 0.085 $yr^{-1}$ for large trees and 0.056 $yr^{-1}$ for small trees in 1977. The RGR of height for Q. mongolica ssp. crispula was 0.122 $yr^{-1}$. The growth curve for DBH of P. densiflora was approximated by the logistic equation: $$DBH(t) = 30 {[1+1.16exp(-0.13 t)]}^{-1}$$ where DBH (t) the DBH (cm) in year t and t is the number of years since 1977. The growth in height of P. densiflora and Q. mongolica ssp. crispula was described by following equations: $$H (t) = 20.2 {[1+0.407exp(-0.137 t)]}^{-1} (P. densiflora)$$ $$H (t) = 30 {[1+20.7exp(-0.122 t)}^{-1} (Q. mongolica ssp. crispula)$$ Where H (t) is the tree height (m) in year t and t is the number of years since 1977 in P. densiflora and 1998 in Q. mongolica ssp. crispula. With these equations we predicted that the height of Q. mongolica ssp. crispula increases from 2 m in 1999 to 20 m in 2029. Therefore, Q. mongolica ssp. crispula and P. densiflora will be approximately the same height in 2029. The years required for succession from a pine forest to an oak forest are expected 33 with the range between 23 and 44 years.

• Journal of the Korean Society of Environmental Restoration Technology
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• v.25 no.2
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• pp.39-53
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• 2022

The purpose of this study is to find out the applicability of LANDIS-II model to Korea. The case study was carried out in Daecheong Dam basin. In order to operate the model, a total of 63,107 cells of 100x100m unit were constructed, each cell consists of ecoregion map, initial communities map, plant physiological data, and climate change prediction data using SSP2-4.5 scenario. Forest distributions of year 2050 and 2100 were predicted by distribution intensity and interference among trees based on field surveys of 147 points in 2020. As a result, trees of decreased distribution area in the future are in the order of Quercus mongolica, Pinus rigida, Pinus densiflora and Robinia pseudoacacia, which characterized vulnerable to the effects of climate change or artificially planted trees. While warm climate trees of Quercus variabilis, Quercus serrata, Quercus acutissima and Quercus aliana are predicted to increase their distribution area in the order. These results analyzed using the LANDIS-II model are consistent with the studies on potential natural vegetation and succession tendency in Korea. In conclusion, the applicability of LANDIS-II model in Korea is highly effective and it is also expected to serve as a scientific basis for determining forest policies on afforestation and restoration.

• Mycobiology
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• v.49 no.5
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• pp.461-468
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• 2021

The genus Laccaria (Hydnangiaceae, Agaricales) plays an important role in forest ecosystems as an ectomycorrhizal fungus, contributing to nutrient cycles through symbiosis with many types of trees. Though understanding Laccaria diversity and distribution patterns, as well as its association with host plants, is fundamental to constructing a balanced plant diversity and conducting effective forest management, previous studies have not been effective in accurately investigating, as they relied heavily on specimen collection alone. To investigate the true diversity and distribution pattern of Laccaria species and determine their host types, we used four different approaches: specimen-based analysis, open database search (ODS), NGS analysis, and species-specific PCR (SSP). As a result, 14 Laccaria species have been confirmed in Korea. Results regarding the species distribution pattern were different between specimen-based analysis and SSP. However, when both were integrated, the exact distribution pattern of each Laccaria species was determined. In addition, the SSP revealed that many Laccaria species have a wide range of host types. This study shows that using these four different approaches is useful in determining the diversity, distribution, and host of ECM fungi. Furthermore, results obtained for Laccaria will serve as a baseline to help understand the role of ECM fungi in forest management in response to climate change.

• Journal of Plant Biology
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• v.3 no.1
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• pp.26-31
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• 1960

1. Mt. Soyo is situated in the central part of Korea, approximately 37$^{\circ}$56'W. Latitude, 127$^{\circ}$4'N. Longitude. This mountain is about 530 meters above sea level, and consists mainly of granites. Above 200 meters the area is covered with oak trees (Quercus mongolica, Q. aliena) with a kind of Rhododendron (Rhododendron mucronulatum, R. schlippenbachii) as undergrowth. About 500 packets of bryophytes were collected by the writer in 1959. 2. The mosses collected in this region were of 68 species belonging to 51 genera. Those species may roughly be divided, as follows; 1) 15 species (22.1%) are distributed also in Europe and North America (Holarctic element). 2) 2 species (2.9%) occur also in Kamchatka and the Aleutians (North Pacific element). 3) 14 species (20.6%) are widely distributed every where (Cosmopolitan element). 4) 19 species (27.9%) occur also in the temperature region of the Far East (East Asiatic element). 5) 3 species (4.4%) occur also in Indomalaya and India (Tropical element). 6) 15 species (22.1%) are endemic to Japan and Korea. 3. The Hepaticae collected in this region are of 11 species belonging to 7 genera. Those may roughly be divided, as follows; 1) 4 species (36.4%) are distributed also in Europe and North America (Holarctc element). 2) 5 species (45.5%) occur also in the temperature region of the Far East (Asiatic element). 3) 1 species (9.1%) occur also in Indomlaya. 4) 1 species (9.1%) are endemic in Japan and Korea. 4. The species which are new to the flora of Korea are as follows; 1) Leucobryum glaucum (L.) Schimp. 2) Psedoleskeopsis dicurvata (Mitt.) Broth. 3) Thuidium delicatulum (Hedw.) Mitt. 4) Dolichotheca perrobustum (Broth.) Broth. 5) Brachiolejeunia sandvicensis (Gott). Evans. 6) Porella vernicosa Lindb. ssp. gracillina (Mitt.) Ando.