[논문]Ecological Niche Overlap and Competition between Quercus mongolica and Quercus dentata Under Soil Water Gradient

Yeon-ok, Seo; Se-Hee, Kim; Eui-Joo, Kim; Yoon-Seo, Kim; Kyeong-Mi, Cho; Jae-Hoon, Park; Ji-Won, Park; JungMin, Lee; Jin Hee, Park; Byoung-Ki, Choi; Young-Han, You

doi:10.7747/jfes.2022.38.4.229

Ecological Niche Overlap and Competition between Quercus mongolica and Quercus dentata Under Soil Water Gradient 원문보기

Journal of forest and environmental science, v.38 no.4, 2022년, pp.229 - 238

Yeon-ok, Seo (Warm Temperate and Subtropical Forest Research Center) , Se-Hee, Kim (Department of Biological Sciences, Kongju National University) , Eui-Joo, Kim (Department of Biological Sciences, Kongju National University) , Yoon-Seo, Kim (Department of Biological Sciences, Kongju National University) , Kyeong-Mi, Cho (Department of Biological Sciences, Kongju National University) , Jae-Hoon, Park (Department of Biological Sciences, Kongju National University) , Ji-Won, Park (Department of Biological Sciences, Kongju National University) , JungMin, Lee (Department of Biological Sciences, Kongju National University) , Jin Hee, Park (Department of Animal and Plant Research, Nakdonggang National Institute of Biological Resources) , Byoung-Ki, Choi (Warm Temperate and Subtropical Forest Research Center) , Young-Han, You (Department of Biological Sciences, Kongju National University)

Abstract ▼ AI-Helper

Q. mongolica and Q. dentata are representative species of deciduous forest communities in Korea and are known to be relatively resistant to soil drying condition among Korean oaks. This study attempted to elucidate the degree of competition and ecological niche characteristics of the two species by comparing the ecological responses of the two species according to soil moisture. Competition between Q. mongolica and Q. dentata was shown to be more intense under the conditions where moisture content was low than under the conditions where moisture content was high. As for the ecological niche overlaps of the two species for soil moisture, the structural traits of plant such as stem diameter overlapped the most, the traits of biomass such as petiole weight overlapped the least, and photosynthetic organ-related traits such as leaf width and length overlapped intermediately. When looking at the competition for soil moisture between the two species, it can be seen that Q. mongolica won in nine traits (leaf width length, leaf lamina length, leaf lamina weight, leaf petiole weight, leaf area, leaves weight, shoot weight, root weight, and plant weight) and Q. dentata won in the remaining seven traits (leaf petiole length, leaves number, stem length, stem diameter, stem weight, shoot length, and root length). Competition between the two species for the moisture environment of the soil was shown to be intense under the conditions where moisture content was low. The degree of competition between Q. dentata and Q. mongolica for soil moisture is high under the conditions where soil moisture content is low, and it is judged that Q. mongolica is more competitive for soil moisture than Q. dentata.

주제어

표/그림 (5)

표 Table 1. Correlation matrix of 16 variables with the first and two principal component scores of principle component analysis (PCA)
그림 Fig. 1. Schematic diagram of seedling for ecological and morphological traits of Quercus seedling.
그림 Fig. 2. Comparison of ecological niche breadth and ecological niche overlap for 16 ecological and morphological traits according to soil moisture changes in Q. mongolica (Qm) and Q. dentata (Qd) (*; larger values when comparing niche breadth between two species).
그림 Fig. 3. Comparison of ecological niche breadth and ecological niche overlap by grouping 16 ecological and morphological traits of soil moisture changes in Q. mongolica (Qm) and Q. dentata (Qd).
그림 Fig. 4. Principal component analysis (PCA) of 16 characteristics of 32 individuals of Q. mongolica (Qm) and Q. dentata (Qd) along with soil moisture gradients (M1-M4).

참고문헌 (44)

Abrams P. 1980. Some comments on measuring niche overlap.？Ecology 61: 44-49.

상세보기
Barbour MG, Burk JH, Pitts WD, Gilliam FS, Schwartz MW. 2015. Terrestrial Plant Ecology. 3rd ed. Mun HT, Jeong YS,？You YH, translator. Hongreung Publishing Company, Seoul,？614 pp.
Bell KL, Bliss LC. 1979. Autecology of Kobresia bellardii: why？winter snow accumulation limits local distribution. Ecol Monogr 49: 377-402.

상세보기
Billings WD, Bliss LC. 1959. An alpine snowbank environment？and its effects on vegetation, plant development, and productivity.？Ecology 40: 388-397.

상세보기
Byun HR, Han YH. 1994. On the existence of the seasonal？drought in the Korean Peninsula. Asia Pac J Atmos Sci 30:？457-467.
Chung SH, Lee ST. 2021. Classification of forest cover types in the？Baekdudaegan, South Korea. J For Environ Sci 37: 269-279.
Chung TH, Lee WC. 1965. A study of the Korean woody plant？zone and favorable region for the growth and proper species. J？Sunkyunkwan Univ 10: 329-366.
Grinnell J. 1917. The niche-relationships of the California Thrasher.？The Auk 34: 427-433.

상세보기
Han SJ, Kim HJ, You YH. 2009. Selection on tolerant oak species？to water flooding for flood plain restoration. J Wetl Res 11: 1-7.
Jang GJ. 2007. Phytosociological studies on the Quercus mongolica forest in Korea. PhD thesis. Kangwon National University,？Chuncheon, Korea. (in Korean)
Jeong HM, Kim HR, You YH. 2009. Growth difference among？saplings of Quercus acutissima, Q. variabilis and Q. mongolica？under the environmental gradients treatment. Korean J Environ？Biol 27: 82-87.
Jeong HM, Kim HR, You YH. 2021. Impact of germination and？initial growth of deciduous six oak species under climate change？environment condition. Korean J Ecol Environ 54: 334-345.

원문보기 상세보기
Jung YH. 2019. Growth response and ecological niche breadth of？Quercus dentata, according to environmental conditions under？climate change. MS thesis. Kongju National University, Gongju,？Korea. (in Korean)
Kim EJ, Jeong YH, Park JH, Lee EP, Lee SY, Lee SI, Hong YS,？Jang RH, Ceung SH, Lee YK, You YH, Cho KT. 2020.？Growth Response and Ecological Niche of Quercus dentata？Thunb. Sapling under the Light, Moisture Content, Soil？Texture and Nutrient Treatment. Korean J Ecol Environ 53:？102-108.

원문보기 상세보기
Kim HD. 2010. Studies on community dynamics of forest vegetation in Bukhansan National Park. PhD thesis. Changwon？National University, Changwon, Korea. (in Korean)
Kim JE, Gil BS. 2000. The Mongolian Oak Forest in Korea.？Wonkwang University Press, Iksan, 511 pp.
Kim JH. 1995. The Stepping-stones for Ecology in Korea.？Yeocheon Kim Jun-ho Professor Retirement Commemoration？Association Thesis Publication Committee, Seoul, pp 317-350.
Kim JH, Mun HT, Kwak YS. 1990. Community structure and soil？properties of the Pinus densiflora forests in limestone areas.？Korean J Ecol 13: 285-295.
Kim JH, Mun HT, Kwak YS. 1991. Community structure and soil？properties of Chinese Cork oak (Quercus variabilis) forests in？limestone area. Korean J Ecol 14: 159-169.
Kim JW, Kim JH. 1994a. Stomatal Control and Strategy Segregation？to Drought Stress in Young Trees of Several Oak Species.？Korean J Ecol 17: 241-249.
Kim JW, Kim JH. 1994b. Comparison of Adjustments to Drought？Stress Among Seedlings of Several Oak Species. J Plant Biol 37:？343-347.
Kim SG, Kwon B, Son Y, Yi MJ. 2018. Carbon storage in an？age-sequence of temperate Quercus mongolica stands in central？Korea. J For Environ Sci 34: 472-480.
Korea Forest Service. 2020. Forest Basic Statistics. https://kfss.forest.go.kr/stat/ptl/main/main.do. Accessed 18 Oct 2021.
Kwon DH, Park HD. 2007. Soil Geography. Hanulbooks, Paju,？pp 56-60.
Lee CS, Lee AN. 2003. Ecological Importance of Water Budget？and Synergistic Effects of Water Stress of Plants due to Air？Pollution and Soil Acidification in Korea. Korean J Ecol 26:？143-150.

원문보기 상세보기
Lee H, An C, Han S, Lee W, Jang K. 2016. Component Analysis？of Acorns of Quercus mongolica and Quercus Variabilis. J For？Environ Sci 32: 103-112.
Lee HJ, You YH. 2009. Ecological Niche Breadth of Q. mongolica and Overlap with Q. acutissima and Q. variabilis along with？Three Environment Gradients. Korean J Environ Biol 27:？191-197.
Lee SY, Kim EJ, Lee EP, Cho KT, Park JH, Lee YK, Chung SH,？Hong YS, Park JH, Choi SS, Kim HR, You YH. 2020.？Analysis of Climate and Topographical Factors of Economical？Forests in Korea to Select the Restoration Safe Site of 5？Dominant Oak Species. Korean J Ecol Environ 53: 427-435.

원문보기 상세보기
Lee TB. 2003. Coloured Flora of Korea. Hyangmunsa, Seoul, pp？200-208.
Levins R. 1968. Evolution in Changing Environments: Some？Theoretical Explorations. Princeton University Press, Princeton,？NJ.
Matsuda K, Mcbride JR. 1989. Germination Characteristics of？Selected California Oak Species. Am Midl Nat 122: 66-76.

상세보기
Menitsky YL. 2005. Oaks of Asia. Science Publishers, Enfield,？NH.？
Noh HJ, Jeong HY. 2002. Easy-to-understand Statistical Analysis？by STATISTICA. Hyungseul Publisher, Seoul, pp 535-556.
Park BH. 2003. Studies on the Niche of four herbal species along？the Environmental Gradient. MS thesis. Seowon University,？Cheongju, Korea. (in Korean)
Park IH, Lee DK, Lee KJ, Moon GS. 1996. Growth, biomass and？net production of Quercus species (I) - with reference to natural？stands of Quercus variabilis, Q. acutissima, Q. dentata, and Q.？mongolica in Kwangju, Kyonggi-Do. J Korean For Soc 85:？76-83.
Pianka ER. 1983. Evolutionary Ecology. 3rd ed. Harper & Row,？New York, NY.
Ryoo SB, Kim YA. 2000. Variation of Evapotranspiration over？Forest Site at Kwangneung: from Fall to Early Winter. Asia Pac？J Atmos Sci 36: 43-50.
Schoener TW. 1970. Nonsynchronous spatial overlap of lizards in patchy habitats. Ecology 51: 408-418.

상세보기
Song CY, Lee SW. 1996. Biomass and Net Primary Productivity in？Natural Forests of Quercus mongolica and Quercus variabilis. J？Korean For Soc 85: 443-452.
Song HK, Lee MJ, Yee S, Kim HJ, Ji YU, Kwon OW. 2003.？Vegetation Structures and Ecological Niche of Quercus mongolica Forests. J Korean For Soc 92: 409-420.
Statsoft INC. 2004. STATISTICA (data analysis software system). Version 7.
Yeochon Association for Ecological Research. 2005. Modern？Ecology Experiment. Kyomunsa, Seoul.
You YH, Lee SY, Lee EP, Kim JE, Kim EJ, Park JW, Roh JY, Lee？JM, Kim MJ, Song SH, Kim YS, Cho KM. 2019.？Development of High-value Use of Broadleaf Forests and？Management Technology by Type: Distribution Status and？Type Classification for Broadleaf Forest Operations. National？Institute of Forest Science, Seoul, 171 pp. (in Korean).
Young JA, Young CG. 1992. Seeds of Woody Plants in North？America. Dioscorides Press, Portland, OR, pp 289-294.

표제어: PCR

동의어: Packet Collision Rate

용어 설명 출처 목록 (6)

용어 설명: PCR은 세균 특이성이 있는 primer를 이용하여 적은 수의 세균이 있을지라도 쉽게 검출할 수 있는 유용한 방법이며, 이를 이용하여 구강 내 치면세균막이나 타액에서 직접 세균을 검출할 수 있게 되었다[8].

내보내기 구분	파일저장 인쇄 메일전송
구성항목	기본정보 상세정보 관리번호, 논문명, 저널/프로시딩명, 저자 , 발행년, 권, 호, 시작페이지, 끝페이지, 발행기관 관리번호, 논문명, 대등논문명, 저자 , 저널/프로시딩명, 발행기관, 발행년, 발행언어, 권, 호, 시작페이지, 끝페이지, ISBN, ISSN, 주제분야, 키워드, 초록(한글), 초록(영문), 저자(소속기관)
저장형식	Text(ASCII format) Excel format RefWorks Direct Export RIS format (for Reference Manager, ProCite, EndNote), Scholar's Aids, Mendeley
메일정보	받는사람 (필수) @ 보내는사람 (선택) @ 제목 내용 KISTI 검색결과 이메일 서비스
안내	총 건의 자료가 검색되었습니다. 다운받으실 자료의 인덱스를 입력하세요. (1-10,000) 검색결과의 순서대로 최대 10,000건 까지 다운로드가 가능합니다. 데이타가 많을 경우 속도가 느려질 수 있습니다.(최대 2~3분 소요) 다운로드 파일은 UTF-8 형태로 저장됩니다. 파일의 내용이 제대로 보이지 않을실 때는 웹브라우저 상단의 보기 -> 인코딩 -> 자동선택 여부를 확인하십시오. ~ Text(ASCII format) Excel format

연합인증