Browse > Article
http://dx.doi.org/10.17663/JWR.2012.14.2.265

Retention properties of organic matters and nutrients in wetland soils and coastal sediments  

Park, Soyoung (국립부경대학교 해양산업개발연구소)
Yi, Yong Min (국립부경대학교 생태공학과)
Yoon, Han-Sam (국립부경대학교 해양산업개발연구소)
Sung, Kijune (국립부경대학교 생태공학과)
Publication Information
Journal of Wetlands Research / v.14, no.2, 2012 , pp. 265-275 More about this Journal
Abstract
As climate change is becoming a growing concern and the importance of water management is increasing, the retention of carbon and nutrients in wetland soils including inland and coastal area has become important. In this study, retention characteristics of organic matter and nutrients of coastal sediment and soils in different types of wetlands such as constructed wetland, natural (inland marsh, estuary, tidal flat) wetlands were investigated. A correlation analysis was also performed to understand the relationship among organic matter properties, nutrient concentrations and soil texture of wetland soils. The degree of retention of organic matter and nitrogen in wetland soils varied with the wetland type. Inland wetlands retain more nitrogen than estuary or coastal wetlands, and natural wetlands retain more organic matter and nitrogen than constructed ones. Coastal sediments in a bay area where seawater circulation is restricted have more nutrients than those in estuary or tidal flats where seawater circulates well. The results showed that the sediment chemical oxygen demand has a high correlation with the total organic carbon and the total nitrogen in the studied area.
Keywords
wetland type; total organic carbon; nitrogen; phosphorous; correlation;
Citations & Related Records
Times Cited By KSCI : 1  (Citation Analysis)
연도 인용수 순위
1 국토해양부. 2010. 해양환경공정시험기준.
2 김경홍, 손승규, 손주원, 주세종. 2006. 해양 퇴적 물내 총탄소 및 유기탄소의 분석기법 고찰. 한국해양환경공학회지 9(4): 235-242.
3 김영윤, 이광섭, 이석모, 강대석, 성기준. 2009. 낙동강 수계 자연습지의 계절별 수질변화특성 분석. 수질보전한국물환경학회지 25(5):713- 719.
4 농업과학기술원, 2000. 토양 및 식물체 분석법.
5 이자연, 강대석, 성기준. 2010. 기준습지 토양특성을 활용한 인공습지의 토양발달 평가. 한국습지학회지 12(1): 1-14.
6 이찬원, 권영택, 양기섭, 장풍국, 한성대. 1998. 폐쇄성 해역의 오염부하 특성과 해역환경변화. 한국해양환경공학회지 1(2): 60-70.
7 최우정, 박청길, 이석모. 1994. 진해만의 빈산소수괴 형성에 관한 수치실험. 한국수산과학회지 27(4): 413-433.
8 한동진, 윤종성. 2005. 폐쇄성 내만에 있어서 수질.저질 상호작용모델링. 한국해안.해양공학회지 17(3): 129-137.
9 황경섭, 허유정, 정종범, 장남익, 안균환, 문세영, 박상. 2008. 탐진강 수계의 토양 및 저질토가 수질에 미치는 영향연구. 대한상하수도학회.한국물환경학회 2008공동추계학술발표회요약논문집, 25-26.
10 해양수산부. 2001. 갯벌생태계 조사 및 지속 가능한 이용방안 연구.
11 해양수산부. 2003. 갯벌생태계 조사 및 지속 가능한 이용방안 연구.
12 Brady NC and Weil RR. 2002. The nature and properties of soils, Prentice Hall, New Jersey, USA.
13 Burford JR and Bremner JM. 1975. Relationships between the denitrification capacities of soils and total water-soluble and readily decomposable soil organic matter. Soil. Biol. Biochem. 7: 389-394.   DOI   ScienceOn
14 Craft CB, Broome SW, Seneca, ED. 1988. Nitrogen, phosphorus and organic carbon pools in natural and transplanted marsh soils. Estuaries 11(4): 272-280.   DOI   ScienceOn
15 Craft CB, Seneca ED, Broome SW. 1991. Loss on ignition and Kjeldahl digestion for estimating organic carbon and total nitrogen in estuarine marsh soils: calibration with dry combustion. Estuaries 14(2): 175-179.   DOI   ScienceOn
16 Howard PJA and Howard DA. 1989. Use of organic carbon and loss-on ignition to estimate soil organic matter in different soil types and horizons. Biology and Fertility of Soils 9: 306-310.
17 Konen ME, Jacobs PM, Burras CL, Talaga BJ, Mason JA. 2002. Equations for predicting soil organic carbon using loss-on ignition for north central U.S. soils. Soil Sci. Soc. Am. J. 66: 1878-1881.   DOI   ScienceOn
18 Leong LE and Tanner PA. 1999. Comparison of methods for determination of organic carbon in marine sediment. Marine Pollution Bulletin 38(10): 875-879.   DOI   ScienceOn
19 Miller CT and Weber WJ. 1984. Modelling organic contaminant partitioning in ground-water systems. Groundwater 22(5): 584-592.   DOI   ScienceOn
20 Mitsch WJ and Gosselink JG. 2000. Wetlands. John Wiley & Son, New York.
21 Post WM, Emanuel WR, Zinke PJ, Stangenberger AG. 1982. Soil carbon pools and world life zones. Nature 298: 156-159.   DOI
22 Sahrawat KL. 2006. Organic matter and mineralizable nitrogen relationships in wetland rice soils. Communications in Soil Science and Plant Analysis 37: 787-796.   DOI   ScienceOn
23 Schulte FE and Hopkins BG. 1996. Estimation of organic matter by weight loss-on ignition, Soil Organic Matter: Analysis and Interpretation. Magdoff, F.R. (eds), SSSA Spec. Publ. 46, SSSA, Madison, WI. pp.21-31.
24 Vos BD, Lettens S, Muys B, Deckers JA. 2007. Walkley-Black analysis of forest soil organic carbon: recovery, limitations and uncertainty. Soil Use and Management 23: 221-229.   DOI   ScienceOn