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ACOMS+ 및 학술지 리포지터리 설명회

  • 한국과학기술정보연구원(KISTI) 서울분원 대회의실(별관 3층)
  • 2024년 07월 03일(수) 13:30
 

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  • ENGLISH
  • P-ISSN2287-8327
  • E-ISSN2288-1220
  • SCOPUS, KCI

Community changes in carabid beetles (Coleoptera: Carabidae) through ecological succession in abandoned paddy fields

Journal of Ecology and Environment / Journal of Ecology and Environment, (P)2287-8327; (E)2288-1220
2011, v.34 no.3, pp.269-278
도윤호 (부산대학교)
정광석 (부산대학교)
Maurice Lineman (부산대학교)
김지윤 (부산대학교)
김항아 (부산대학교)
주기재 (부산대학교)

Abstract

Carabid beetle community changes in paddy fields, abandoned paddy fields, and mountains were investigated to understand differences in species diversity and composition of different habitat types in small agricultural landscapes in South Korea. A total of 2,938 individuals from 37 species were identified and classified from the studied habitats. Diversity in the mountains was higher than that in abandoned paddy fields. As the number of years since abandonment increased, the diversity and stability of the carabid beetle community also increased. Abandoned paddy fields in some paddy field areas and adjoining mountainous areas, left with preconditions for management and control, have provided the opportunity to improve the diversity and habitat of small agricultural landscapes. Species composition changed continuously from the paddy fields to the mountains, in accordance with individual species habitat preferences. Abandoned paddy fields in small agricultural landscapes are believed to play an important role as transitional buffer zones between paddy fields and the adjacent mountainous areas.

keywords
abandoned paddy field, agricultural landscape, carabid beetle, ecological succession

참고문헌

1.

Alhoniemi E, Himberg J, Parhankangas J, Vesanto J. 2000. SOM Toolbox for Matlab. SOM Toolbox Team, Helsinki University, Espoo.

2.

Berger WH, Parker FL. 1970. Diversity of planktonic Foraminifera in deep-sea sediments. Science 168: 1345-1347.

3.

Blake S, Foster GN, Fisher GEJ, Ligertwood GL. 1996. Effects of management practices on the carabid faunas of newly established wildflower meadows in southern Scotland. Ann Zool Fenn 33: 139-147.

4.

Chae JH, Park JY, Kim JS. 2007. Distribution of tertiary and change of population in rural area. Rural Econ 30: 109-127. (in Korean with English summary)

5.

Cho HJ, Ra JH, Sagong JH, Ryu YS. 2009. The type classification and characteristic analysis of biotope in rural areas. J Korean Soc Rural Plann 15: 19-32. (in Korean with English summary)

6.

Chon TS, Park YS, Moon KH, Cha EY. 1996. Patternizing communities by using an artificial neural network. Ecol Model 90: 69-78.

7.

Comín FA, Romero JA, Hernández O, Menéndez M. 2001. Restoration of wetlands from abandoned rice fields for nutrient removal, and biological community and landscape diversity. Restor Ecol 9: 201-208.

8.

Corbet SA. 1995. Insects, plants and succession: advantages of long-term set-aside. Agric Ecosyst Environ 53: 201-217.

9.

Do Y, Moon TY. 2002. Succession of insect communities by desiccation of bog Hwaemneup at Mt. Wonhyosan, Yangsan. J Korean Wetl Soc 4: 13-22. (in Korean with English summary)

10.

Do YN, Moon TY, Joo GJ. 2007. Application of the carabid beetles as ecological indicator species for wetland characterization and monitoring in Busan and Gyeongsangnam-do. Korean J Environ Ecol 21: 22-29. (in Korean with English summary)

11.

Egler FE. 1954. Vegetation science concepts, I. Initial floristic composition, a factor in old-field vegetation development. Vegetatio 4: 412-417.

12.

Eyre MD, Luff ML, Rushton SP. 1990. The ground beetle (Coleoptera, Carabidae) fauna of intensively managed agricultural grasslands in northern England and southern Scotland. Pedobiologia 34: 11-18.

13.

Fournier E, Loreau M. 2001. Respective roles of recent hedges and forest patch remnants in the maintenance of ground-beetle (Coleoptera: Carabidae) diversity in an agricultural landscape. Landsc Ecol 16: 17-32.

14.

Garcia HL, Gonzalez ML. 2004. Self-organizing map and clustering for wastewater treatment monitoring. Eng Appl Artif Intell 17: 215-225.

15.

Gevrey M, Dimopoulos I, Lek S. 2003. Review and comparison of methods to study the contribution of variables in artificial neural network models. Ecol Model 160: 249-264.

16.

Giraudel JL, Lek S. 2001. A comparison of self-organizing map algorithm and some conventional statistical methods for ecological community ordination. Ecol Model 146: 329-339.

17.

Griffiths GJK, Winder L, Holland JM, Thomas CFG, Williams E. 2007. The representation and functional composition of carabid and staphylinid beetles in different field boundary types at a farm-scale. Biol Conserv 135: 145-152.

18.

Hakoyama S, Tanaka H, Agata W, Takeda T. 1977. Studies on weed vegetation of non-cultivated paddy fields,1: The vegetation of non-cultivated paddy fields in the north-western parts of Fukuoka prefecture. Jpn J Crop Sci 46: 219-227. (in Japanese with English summary)

19.

Hengeveld R. 1987. Scales of variation: their distinction and ecological importance. Ann Zool Fenn 24: 195-202.

20.

Huke RE, Huke EH. 1997. Rice Area by Type of Culture: South, Southeast, and East Asia maps. International Rice Research Institute, Manila.

21.

Huusela-Veistola E. 1996. Effects of pesticide use and cultivation techniques on ground beetles (Col., Carabidae) in cereal fields. Ann Zool Fenn 33: 197-205.

22.

Hwang YS. 2010. Policy issues based on the survey of farmland ownership and utilization: focused on a case study of a village in Haman semi-mountainous rural area. J Reg Stud 18: 151-180. (in Korean with English summary)

23.

Jeong KS, Hong DG, Byeon MS, Jeong JC, Kim HG, Kim DK, Joo GJ. 2010. Stream modification patterns in a river basin: field survey and self-organizing map (SOM) application. Ecol Inform 5: 293-303.

24.

Kalteh AM, Hjorth P, Berndtsson R. 2008. Review of the self-organizing map (SOM) approach in water resources: analysis, modelling and application. Environ Model Softw 23: 835-845.

25.

Kang HK, Ohkuro T, Nikkuni S, Aoda T, Arita H. 2004. Factors affecting plant succession in abandoned paddy fields in mountainous regions: case study in Ena city, Gifu prefecture, central Japan. J Rural Plann Assoc 23: 63-70. (in Japanese with English summary)

26.

Kato M. 2001. ‘Satoyama’ and biodiversity conservation: ‘Satoyama’ as important insect habitats. Glob Environ Res 5: 135-149.

27.

Katoh K, Sakai S, Takahashi T. 2009. Factors maintaining species diversity in satoyama, a traditional agricultural landscape of Japan. Biol Conserv 142: 1930-1936.

28.

Kiang MY, Kulkarni UR, St Louis RS. 2001. Circular/wrap-around self-organizing map networks: an empirical study in clustering and classification. J Oper Res Soc 52: 93-101.

29.

Kinnunen H, Tiainen J. 1999. Carabid distribution in a farmland mosaic: the effect of patch type and location. Ann Zool Fenn 36: 149-158.

30.

Kohonen O, Hauta-Kasari M. 2008. Distance measures in the training phase of self-organizing map for color histogram generation in spectral image retrieval. J Imaging Sci Technol 52: 1-11.

31.

Kohonen T. 1984. Self-Organization and Associative Memory. Springer-Verlag, Berlin.

32.

Kohonen T. 1998. The self-organizing map. Neurocomputing 21: 1-6.

33.

Kohonen T. 2000. Self-Organizing Maps. Springer-Verlag, Berlin.

34.

Korea Rural Economic Institute. 2005. Current condition of abandoned or idle farm land and policy direction. Korea Rural Economic Institute, Seoul. (in Korean with English summary)

35.

Kromp B. 1999. Carabid beetles in sustainable agriculture: a review on pest control efficacy, cultivation impacts and enhancement. Agric Ecosyst Environ 74: 187-228.

36.

Kruk A, Lek S, Park YS, Penczak T. 2007. Fish assemblages in the large lowland Narew River system (Poland): application of the self-organizing map algorithm. Ecol Model 203: 45-61.

37.

Lasne E, Bergerot B, Lek S, Laffaille P. 2007. Fish zonation and indicator species for the evaluation of the ecological status of rivers: example of the Loire basin (France). River Res Appl 23: 877-890.

38.

Lee CS, You YH, Robinson GR. 2002. Secondary succession and natural habitat restoration in abandoned rice fields of central Korea. Restor Ecol 10: 306-314.

39.

Lek-Ang S, Park YS, Ait-Mouloud S, Deharveng L. 2007. Collembolan communities in a peat bog versus surrounding forest analyzed by using self-organizing map. Ecol Model 203: 9-17.

40.

Luff ML, Eyre MD, Rushton SP. 1989. Classification and ordination of habitats of ground beetles (Coleoptera, Carabidae) in north-east England. J Biogeogr 16: 121-130.

41.

Maclean L, Dawe DC, Hardy B, Hettel GP. 2002. Rice Almanac. 3rd ed. International Rice Research Institute, Los Baños.

42.

Margalef R. 1958. Information theory in ecology. Gen Syst 3: 36-71.

43.

Niemelä J, Kotze DJ. 2009. Carabid beetle assemblages along urban to rural gradients: a review. Landsc Urban Plann 92: 65-71.

44.

Paik CH, Lee GH, Kang JG, Jeon YK, Choi MY, Seo HY. 2009. Plant flora and insect fauna in the fallow paddy fields of Jeonnam and Jeonbuk Province. Korean J Appl Entomol 48: 285-294. (in Korean with English summary)

45.

Park YS, Song MY, Park YC, Oh KH, Cho E, Chon TS. 2007. Community patterns of benthic macroinvertebrates collected on the national scale in Korea. Ecol Model 203: 26-33.

46.

Penczak T, Kruk A, Grzybkowska M, Dukowska M. 2006. Patterning of impoundment impact on chironomid assemblages and their environment with use of the self-organizing map (SOM). Acta Oecol 30: 312-321.

47.

Petit S, Usher MB. 1998. Biodiversity in agricultural landscapes: the ground beetle communities of woody uncultivated habitats. Biodivers Conserv 7: 1549-1561.

48.

Pielou EC. 1975. Ecological Diversity. Wiley-Interscience, New York, NY.

49.

Sanderson RA, Rushton SP, Cherrill AJ, Byrne JP. 1995. Soil, vegetation and space: an analysis of their effects on the invertebrate communities of a moorland in north-east England. J Appl Ecol 32: 506-518.

50.

Shannon CE, Weaver W. 1949. The Mathematical Theory of Communication. University of Illinois Press, Urbana, IL.

51.

Song MY, Park YS, Kwak IS, Woo H, Chon TS. 2006. Characterization of benthic macroinvertebrate communities in a restored stream by using self-organizing map. Ecol Inform 1: 295-305.

52.

Southwood TRE, Brown VK, Reader PM. 1979. The relationships of plant and insect diversities in succession. Biol J Linn Soc 12: 327-348.

53.

Su MC, Liu TK, Chang HT. 2002. Improving the self-organizing feature map algorithm using an efficient initialization scheme. Tamkang J Sci Eng 5: 35-48.

54.

Thomas F, Folgarait P, Lavelle P, Rossi JP. 2004. Soil macrofaunal communities along an abandoned rice field chronosequence in Northern Argentina. Appl Soil Ecol 27: 23-29.

55.

Uematsu Y, Koga T, Mitsuhashi H, Ushimaru A. 2010. Abandonment and intensified use of agricultural land decrease habitats of rare herbs in semi-natural grasslands. Agric Ecosyst Environ 135: 304-309.

56.

Varchola JM, Dunn JP. 1999. Changes in ground beetle (Coleoptera: Carabidae) assemblages in farming systems bordered by complex or simple roadside vegetation. Agric Ecosyst Environ 73: 41-49.

57.

Yamada S, Okubo S, Kitagawa Y, Takeuchi K. 2007. Restoration of weed communities in abandoned rice paddy fields in the Tama Hills, central Japan. Agric Ecosyst Environ 119: 88-102.

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