[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.5141/JEFB.2007.30.1.101

Which Environmental Factors Caused Lammas Shoot Growth of Korean Red Pine?

Lee, Chang-Seok (Faculty of Environment and Life Sciences, Seoul Women's University)
Song, Hye-Gyung (Department of Biology, Graduate School of Seoul Women's University)
Kim, Hye-Soo (Department of Biology, Graduate School of Seoul Women's University)
Lee, Bit-Na-Ra (Department of Biology, Graduate School of Seoul Women's University)
Pi, Jeong-Hoon (Department of Biology, Graduate School of Seoul Women's University)
Cho, Yong-Chan (Department of Biology, Graduate School of Seoul Women's University)
Seol, Eun-Sil (Department of Biology, Graduate School of Seoul Women's University)
Oh, Woo-Seok (Department of Biology, Graduate School of Seoul Women's University)
Park, Sung-Ae (Department of Biology, Graduate School of Seoul Women's University)
Lee, Seon-Mi (Department of Biology, Graduate School of Seoul Women's University)

Publication Information

Journal of Ecology and Environment / v.30, no.1, 2007 , pp. 101-105 More about this Journal

Abstract

Lammas growth, a rare phenomenon for Korean red pine (Pinus densiflora), occurred in 2006. Lammas shoots showed higher frequency and longer length in Seoul's hotter urban center than in urban boundary or suburban forest sites. Frequency and length showed a close correlation with urbanization density and vegetation cover expressed in NDVI. Air temperature in the late summer of 2006 was more than $1^{\circ}C$ higher than an average year. Of the predominant environmental signals that modulate bud flush, only temperature changed significantly during the year. Differences in temperature between the urban centers, urban boundaries and suburban forests correlated with varying land-use density. The rise in temperature likely spurred lammas growth of the Korean red pine. Symptoms of climate change are being detected throughout the world, and its consequences will be clearer in the future. Considerate interest in the responses of ecological systems to the variable changes is required to prepare for unforeseeable crises. Monitoring of diverse ecological phenomena at Long Term Ecological Research sites could offer harbingers of change.

Keywords

Climate change; Korean red pine; Lammas growth; Land use pattern; Urbanization;

Citations & Related Records

Reference

1	Campbell RK, Sorensen FC. 1978. Effect of test environment on expression of clines and on delimitation of seed zones in Douglas-fir. Theor Appl Genet 51:233-246 DOI ScienceOn
2	Sorensen FC. 1983. Geographic variation in seedling Douglas-fir (Pseudotsuga menziesii) from the western Siskiyou Mountains of Oregon. Ecology 64: 696-702 DOI ScienceOn
3	Loopstra C. 1984. Patterns of genetic variation within and among breeding zones of Douglas-fir in southwest Oregon. (MS thesis), Oregon State University, Corvalis, Oregon. 57p
4	Middelkoop H, Daamen K, Gellens D, Grabs W, Kwaijk JCJ, Lang H, Parmet BWAH, Schadler BWAH, Schulla J, Wilke K. 2001. Impact of climate change on hydrological regimes and water resources management in the Rhine Basin. Climatic Change 49: 105-128 DOI ScienceOn
5	Oke TR. 1987. Boundary Layer Climates (2nd ed.). Routledge, London
6	Rehfeldt GE. 1983. Genetic variability within Douglas-fir populationsimplications for tree improvement. Silvae Genet 32: 9-14
7	Roth M, Oke TR. 1995. Relative efficiencies of turbulent transfer of heat, mass, and momentum over a patchy urban surface. J Atmos Sci 52: 1863-1874 DOI ScienceOn
8	SAS Institute. 2001. PROC user's manual, version 6th ed. SAS Institute, Cary, NC
9	Seoul. 2000. Seoul metropolitan biotop map. Seoul City, Seoul
10	Steiner KC. 1979. Variation in bud-burst timing among populations of interior Douglas-fir. Silvae Genet 28: 76-79
11	Upmanis H, Eliasson I, Lindqvist S. 1998. The influence of green areas on nocturnal temperatures in a high latitude city (Goteborg, Sweden). Internat J Climat 18: 681-700 DOI ScienceOn
12	Cleugh HA, Oke TR. 1986. Suburban-rural energy balance comparisons in summer for Vancouver, BC. Boundary-Layer Meteorology 36: 351-369 DOI
13	Henry, JA, Dicks SE. 1987. Association of urban temperatures with land use and surface materials. Landsc Urban Plan 14: 21-29 DOI ScienceOn
14	Dietrichson J. 1964. The selection problem and growth rhythm. Silvae Genet 13: 178-184
15	Henry JA, Dicks SE, Marotz GA. 1985. Urban and rural humidity distributions: relationships to surface materials and land use. J Climatology 5: 53-62 DOI
16	Bonan G. 2000. The microclimates of a suburban Colorado (USA) landscapes and implications for planning and design. Landsc Urban Plan 49: 97-114 DOI ScienceOn
17	Campbell RK, Sugano AI. 1975. Phenology of bud burst in Douglas-fir related to provenance, photoperiod, chilling and flushing temperature. Bot Gaz 136: 290-298 DOI ScienceOn
18	Environmental System Research Institute (ESRI). 2005. ArcView GIS. Environmental System Research Institute, Inc. New York, USA
19	Grimmond CSB. 1992. The suburban energy balance: methodological considerations and results for a mid-latitude west coast city under winter and spring conditions. Internat J Climat 12: 481-497 DOI
20	Hanninen H. 1995. Effects of climatic change on trees from cool and temperate regions: an ecophysiological approach to modeling of bud burst phenology. Can J Bot 73: 183-199 DOI ScienceOn
21	Jensen JR 1996. Introductory digital image processing: a remote sensing perspective. Prentice Hall, Upper Saddle River, New Jersey, USA
22	Kaya Z, Adams WT, Campbell RK. 1994. Adaptive significance of intermittent shoot growth in Douglas-fir seedlings. Tree physiol 14: 1277-1289 DOI ScienceOn
23	KMA (Korea Metrological Administration). 2004. Annual Climatological Report. Korea Metrological Administration, Seoul (in Korean)
24	Kwadijk J 1993. The impact of climate change on the discharge of the River Rhine. (PhD Thesis) Utrecht University, Utrecht, The Netherlands and Netherlands Geographical Studies 171
25	Bigras FJ, D'Aoust LD. 1993. Influence of photoperiod on shoot and root frost tolerance and bud phenology of white spruce seedlings (Picea glauca). Can J For Res 23: 219-228 DOI ScienceOn
26	Landsberg HE. 1981. The urban climate. Academic Press, New York
27	Lee C-S, Lee A-N, Cho Y-C. 2007. Restoration planning of the Seoul Metropolitan area, Korea toward eco-city. In: Urban Forests (Carreiro MM ed). Springer, New York. (In press)
28	Atkinson BW. 1985. The urban atmosphere. Cambridge University Press, Cambridge

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