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RESEARCH ARTICLE
Contents Vol 15(3)

Temporal and spatial characteristics of forest fires in South Korea between 1970 and 2003

Byungdoo Lee A , Pil Sun Park B C and Joosang Chung B
+ Author Affiliations
- Author Affiliations

A Division of Forest Fire, Korea Forest Research Institute, 207, Cheongyangni-2 dong, Dongdaemun-gu, Seoul 130-712, South Korea.

B Department of Forest Sciences, Seoul National University, San 56-1, Sillim-dong, Kwanak-gu, Seoul 151-921, South Korea.

C Corresponding author. Email: pspark@snu.ac.kr

International Journal of Wildland Fire 15(3) 389-396 https://doi.org/10.1071/WF05090
Submitted: 23 September 2005  Accepted: 21 April 2006   Published: 5 September 2006

Abstract

Information on the temporal and spatial patterns of forest fires can contribute to efficient forest fire management. To evaluate the readjustment of forest fire precautionary periods and to provide information for forest fire prevention and suppression strategies, the temporal and spatial characteristics of forest fire occurrences and spread in Korea were analysed using statistics from 1970 to 2003. Monthly forest fire occurrences and burned area were examined using time-series analysis, and F-tests were conducted among forest fire occurrences, burned area, and fire area growth rate to understand monthly forest fire characteristics. To understand the spatial characteristics of forest fires, cities and counties with similar forest fire characteristics were grouped based on cluster analysis of forest fire occurrences and spread characteristics. A seasonal exponential smoothing model was selected for forest fire occurrences and burned area. The number of mean annual forest fire occurrences was 429, and mean annual burned area was 2908 ha year–1 in Korea. The seasonal differences in forest fire characteristics were clearly distinguished, with 61% of total forest fire occurrences and 90% of total burned area being in March and April. Forest fire precautionary periods are suggested based on forest fire occurrence patterns. A total of 226 cities and counties throughout the country were classified into three groups. Group 1, which had frequent forest fire occurrences with smaller burned areas and slower fire growth area rates, was distributed in the western part of Korea and metropolitan regions. Group 3, which had a relatively small number of forest fire occurrences but larger burned areas and fast growth rates, was located in the central inland region and the eastern part of the Taeback Mountain Range. Group 2 had characteristics intermediate between those of group 1 and group 3.


References


Barney RJ, Stocks BJ (1983) Fire frequencies during the suppression period. In ‘The role of fire in northern circumpolar ecosystems’. (Eds RW Wein, DA MacLean) pp. 45–62. (John Wiley and Sons: New York)

Crimmins MA , Comrie AC (2004) Interactions between antecedent climate and wildfire variability across south-eastern Arizona. International Journal of Wildland Fire  13, 455–466.
Crossref | GoogleScholarGoogle Scholar | Everitt BS (1980) ‘Cluster analysis.’ (Halsted Press: New York)

Fox MD, Fox BJ (1987) The role of fire in the scleromorphic forests and shrublands of eastern Australia. In ‘The role of fire in ecological systems’. (Ed. L Trabaub) pp. 23–48. (SPB Academic Publishing: The Hague)

Gill AM (1975) Fire and the Australian flora: a review. Australian Forestry  38, 4–25.
Gill AM (1981) Post-settlement fire history in the Victorian landscape. In ‘Fire and the Australian biota’. (Eds AM Gill, RH Groves, IR Noble) pp. 77–98. (Australian Academy of Science: Canberra)

Grissino-Mayer HD (1999) Modeling fire interval data from the American South-west with the Weibull Distribution. International Journal of Wildland Fire  9, 37–50.
Crossref | GoogleScholarGoogle Scholar | Hamilton JD (1994) ‘Time-series analysis.’ (Princeton University Press: Princeton, NJ)

Kalabokidis KD, Gatzojannis S , Galatsidas S (2002) Introducing wildfire into forest management planning: towards a conceptual approach. Forest Ecology and Management  158, 41–50.
Crossref | GoogleScholarGoogle Scholar | Korea Forest Service (2004) ‘Statistical analysis of forest fire in Korea.’ (Korea Forest Service: Daejeon, Korea)

Korea Meteorological Administration (2004) ‘Annual climatological report.’ (Korea Meteorological Administration: Seoul, Korea)

Kruger FJ, Bigalke RC (1984) Fire in fynbos. In ‘Ecological effects of fire in South African ecosystems’. (Eds PV Boozen, NM Tainton) pp. 67–114. (Springer-Verlag: New York)

Lee BD, Chung JS, Kim HH , Lee SY (2001) Analyzing spread rate of Samcheok forest fire broken out in 2000 using GIS. Journal of Korean Forestry Society  90, 781–787.
SAS Institute (2003) ‘SAS 9.1 help and documentation.’ (SAS Institute: NC, USA)

Schoenberg FP, Peng R, Huang Z , Rundel P (2003) Detection of non-linearities in the dependence of burn area on fuel age and climate variables. International Journal of Wildland Fire  12, 1–6.
Crossref | GoogleScholarGoogle Scholar | Whelan RJ (1995) ‘The ecology of fire.’ (Cambridge University Press: Cambridge)