Journal of Environmental Impact Assessment (환경영향평가)

Korean Society of Environmental Impact Assessment (한국환경영향평가학회)
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Comparison of Flooding Tolerance for the Selection of Plants in Vegetation-Based Low Impact Development Facilities

식생기반형 LID 시설의 식재식물 선정을 위한 내침수성 비교

  • Lee, Eun-Yeob (Dept. of Urban Environment Research, Land & Housing Institute) ;
  • Hyun, Kyoung-Hak (Dept. of Urban Environment Research, Land & Housing Institute) ;
  • Hou, Jin-Sung (Dept. of Urban Environment Research, Land & Housing Institute) ;
  • Park, Mi-Ok (Eco Green Center, Korea Nazarene University) ;
  • Koo, Bon-Hak (Dept. of Environmental Landscape Architecture, Sangmyung University)
  • Received : 2014.11.11
  • Accepted : 2014.12.16
  • Published : 2014.12.31
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Abstract

In this study, 10 species of plants with high adaptability to aquatic environments were compared for selecting plant species suitable for vegetation-based low impact development (LID) facilities. The flooding tolerances of the plants were tested by analyzing their growth status under half-immersion and full-immersion conditions, with varying durations of immersion. In decreasing order of flooding tolerance, the comparative analysis of plant height and leaf width is as follows: Hemerocallis fulva, Juncus effusus var. decipiens, Iris pseudoacorus, Phragmites communis TRIN, Typha orientalis C.Presl, Aster koraiensis Nakai, Iris sanguinea, Equisetum hyemale, Acorus calamus. Specifically, Hemerocallis fulva, Juncus effusus var. decipiens. Iris pseudoacorus showed excellent growth status under both immersion conditions. Iris sanguinea and Equisetum hyemale. withered to death by around day 27 of the experiment, but their flooding tolerance was confirmed to be relatively high. Iris pseudoacoru showed flooding tolerance under the half-immersion condition unlike under the full-immersion condition, when compared on day 21 of the experiment. Aster koraiensis Nakai also thrived better under the half-immersion condition, proving to be a highly immersion-resistant species. On the basis of the results of this experiment, Hemerocallis fulva, Juncus effusus var. decipiens and Iris pseudoacorus, Typha orientalis C.Presl were selected as species suitable for vegetation-based LID facilities.

본 연구는 식생기반형 LID 시설에 적합한 식물선정을 위해 수환경 적응도가 높은 10종의 식물을 반침수와 완전침수 조건에서 침수기간별 생육상태를 조사하여 내침수성을 비교하였다. 침수기간별 수고, 엽폭을 비교 분석한 결과, 내침수성은 원추리 > 골풀 > 노란꽃창포 > 갈대 > 부들 > 벌개미취 > 붓꽃 > 속새 > 창포 순으로 나타났다. 특히, 원추리, 골풀, 노란꽃창포는 두가지 침수조건에서 모두 양호한 생장을 보였으며, 붓꽃, 속새는 27일 전후로 고사되었으나 내침수성이 비교적 강한 것을 확인할 수 있었다. 반침 수구 조건에서 21일 기준으로 완전침수구와 달리 노란꽃창포가 내침수성이 매우 강한 식물로 나타났으며, 벌개미취 또한 양호한 생장을 하며 내침수성이 강한 것으로 나타났다. 본 실험을 통해 식생기반형 LID 시설에 적합한 식물로 원추리, 골풀, 노란꽃창포가 선정되었으며, 벌개미취, 붓꽃, 속새 또한 침수기간에 따른 이용 가능성을 확인하였다.

Keywords

References

  1. 김동현, 최희선. 2013. 수변지역에서의 저영향개발 기법 적용을 위한 계획과정 도출 및 모의효과, 환경정책연구 12(1): 37-58. (Kim, D. and H. Choi. 2013. The Planning Process and Sinulation for Low Impact Development(LID) in Waterfront Area. Korea Environment Institute.)
  2. 김미경, 이경환, 박기성, 박주석. 2007. 제주도의 자연재해 경감을 위한 분산형 빗물관리 방안, 빗물 1(1): 57-63. (Kim, M., Lee, K., Bang, K. and Park, J. 2007. Decentralized Rainwater Management Plan for Mitigation of Natural Disaster in Jeju Island, Korea. Journal of Society of Rain Masters. 1(1): 57-63.)
  3. 김영란. 2007. 빗물관리시설 설치 및 관리 매뉴얼 작성, 서울시정개발연구원 (Kim, Y. 2007. Manual for Implementation and Maintenance of the Rainwater and Infiltration Facilities, Seoul Development Institute.)
  4. 김이호, 김영민, 권경호, 이상호, 이정훈. 2006. 물순환 건전화를 위한 공동주택 우수저류침투시설 설계기법 개발, 대한상하수도학회.한국환경물학회, 2006년 공동 춘계학술발표대회 논문요약집 (Kim, R., Kim, Y., Kwon, K., Lee, S. and Lee, J. 2006. Development of Design Methodology of Rainwater Utilization Facilities in Building Complexes for Sound Water Cycle. Common proceedings for spring conference of KSWW and KSWE.)
  5. 박종민, 최건호. 2001. 호소사면 녹화용 식물 선정을 위한 몇가지 목본식물의 내침수성에 관한 연구, 한국환경복원녹화기술학회지 4(2): 45-51. (Park, J. and Choi, G. 2001. Study on the Flooding Tolerance of Some Woody Plants for Selecting Useful Revegetation Plants in Lake and Marsh Slopes. The Korea Society For Environmental Restoration And Revegetation Technology. 4(2): 42-51)
  6. 박종민. 2002. 호소사면 녹화용 식물선정을 위한 초본식물의 내침수성 비교, 한국환경복원녹화기술학회지 5(2): 25-33. (Park, J. 2002. Comparing of Flooding Tolerance of Herbaceous Plants for Selecting Useful Revegetation Plants in Shoreline Slopes of Lake. The Korea Society For Environmental Restoration And Revegetation Technology. 5(2): 25-33)
  7. 서주환, 이인규. 2013. LID 기술적용을 통한 공동주택단지 물순환 개선 연구, 한국조경학회지 41(5): 68-77. (Suh, J. and Lee, I. 2013. The Water Circulation Improvement of Apartment Complex by applying LID Technologies. Journal of the Korean Institute of Landscape Architecture. 41(5): 68-77)
  8. 이상진. 2013. 저영향개발 기반의 친환경 도시계획.녹색기술정보 기술동향보고서, pp. 133-139. (Lee, S., 2013. Environmental-friendly Urban Design based on Low Impact Development, Green Technology Information Report: 133-139.)
  9. 이태구. 2008. 외국의 빗물이용 사례, 도시문제 43(476): 42-57. (Lee, T., 2008. Cases of Rainwater Utilization in Foreign Country. Public Officials Benefit Association. 43(476): 42-57.)
  10. 임용균. 2011. 친환경적 도시개발을 위한 LID 기술 적용에 대한 연구, 부산대학교 대학원 박사학위논문 (Lim, Y., 2011. (A) study of LID technologies for friendly environmental urban development, Ph.D dissertation, University of Pusan National.)
  11. 최인호. 2006. 3단계 자연물순환체계 계획방법과 택지계획에서의 현장적용 연구, 협성대학교대학원 석사학위논문 (Choi, Inho. 2006. A Study on Planning method of 3-tier Natural Water Circulation System and the Application in Load Planning, Master's Thesis, University of Hyupsung.)
  12. 환경부. 2009. LID 기법을 활용한 자연형 비점오염 관리방안 마련 (Ministry of Environment of Korea. 2009. Natural Non-Point Source Management using LID.)
  13. Bedan E. S. and Clausen J. C. 2009. Stormwater runoff quality and quantity from traditional and low impact development watersheds, Journal of the Amerian Water Resources Association, 45(4): 998-1008. https://doi.org/10.1111/j.1752-1688.2009.00342.x
  14. Bert Hidding., Judith M. S. and Elisabeth S. B. 2014. Flooding tolerance and horizontal expansion of wetland plants, Aquatic Botany 113: 83-89. https://doi.org/10.1016/j.aquabot.2013.11.003
  15. Center for Watershed Protection and New York State Department of Environmental Conservation. 2010. New York State Stormwater Management Design Manual. New York State.
  16. Ewing, K. 1996. Tolerance of four wetland plant species to flooding and sediment deposition, Environ, Exp, Bot, 36(20): 131-146. https://doi.org/10.1016/0098-8472(96)01000-3
  17. Frye, J. and Grosse, W. 1992. Growth response to flooding and recovery of deciduous tree, Zeitschrift fur Naturforschung 47, 683-689.
  18. Glenz, C., Schlaepfer. R., Lorgulescu. I. and Kienast, F. 2006. Flooding tolerance of Central European tree and shrub species, Forest Ecology and Management 235: 1-13. https://doi.org/10.1016/j.foreco.2006.05.065
  19. Hook, D. D. 1984. Adaptation to flooding with fresh water, In: Kozlowski, T.T.(Ed.), Flooding and Plant Growth, Academic Press, Orlando, pp.265-294.
  20. Hyun, K. H. and Lee, J. M. 2013. Characteristics of heavy metals in soil in infiltration splash blocks and rain gardens for management of roof runoff from apartment buildings, Desalination and Water Treatment, 51: 4146-4154. https://doi.org/10.1080/19443994.2013.781111
  21. Hyun, K. H., Lee, K. H., Oh, J. J., Kim, G. T., Kim, J. N., Kim, Y. W. and Jin, S. W. 2008. Application of the Rainwater Management and Cnstructed Wetland System for Imlpementation of Watercycle in Asan New town, Land & Housing Institute
  22. Kern Ewing. 1996. Tolerance of four wetland plant species to flooding and sediment deposition, Environmental and Experimental Botany 36(2): 131-146. Environ, Exp, Bot, 36(20): 131-146. https://doi.org/10.1016/0098-8472(96)01000-3

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