本研究期間共分成6個試程，平均流過時間3~8小時，污染物平均去除率(MRE)，SS為10%~36%、BOD為20%~34%、氨氮為15%~46%、TKN為11%~29%、磷酸鹽為51%~89%、TP為27%~38%。而以一階動力模式所推導出之一階反應速率常數K值，其迴歸結果：SS為0.077 (1/hr)、BOD為0.043 (1/hr)、氨氮為0.056 (1/hr)、TKN為0.057 (1/hr)、磷酸鹽為0.288 (1/hr)、TP為0.063 (1/hr)。
　　溼地植物調查結果發現12種植物，以海馬齒、鹽地鼠尾粟及裸花鹻蓬佔絕大部分，其他常見的尚有鳥類、蛇、鼠、爬蟲類、昆蟲、魚、貝、螺等。

　　In this study, the average through time (ATT) tested were 3~8 hours. The mass removal efficiency (MRE)：SS:10%~36%、BOD:20%~34%、NH4-N:15%~46%、TKN:11%~29%、PO4-P:51%~89%、TP:27%~38%. After regression, the kinetic constant, K, “K values” of the first order kinetic model was as follows：SS:0.077 (1/hr)、BOD:0.043 (1/hr)、NH4-N:0.056 (1/hr)、TKN:0.057 (1/hr)、PO4-P:0.288 (1/hr)、TP:0.063 (1/hr).
　　We found 12 different kinds of plants in the botanical investigation. Among them, Sesuvium portulacastrum (L.) L.、Sporobolus virginicus (L.) Kunth. and Suaeda nudiflora Moq. were the most commonly seen. Other commonly seen were birds、snakes、rats、reptile、insects、fishs、shellfishs and spiral shells etc.

中文部分
張立弘，「生活污水之濕地處理及再利用研究」，國立屏東科技大學碩士論文，2001。
「臺灣沿海濕地資源簡介」網址http://www.bird.org.tw/report/wetland/define.html
郭振泰、楊州斌，「濕地水質及生態數學模式之發展與應用」，2001。
Mitsch Willian J. & Gosselink James G. 作；章盛傑，邱文雅譯，「濕地」，地景，1998。
Sawyer Clair N., McCarty Perry L., Parkin Gene 著；蕭薀華，傅崇德，許鼎居譯，「環境工程化學」，美商麥格羅希爾出版，滄海發行，1995。
歐陽嶠暉，「下水道工程學」，長松出版社，民國69年。
溫清光等，「自然淨化功能之強化－河川高灘地漫地流處理法之研究」，國立成功大學環工系研究報告，1996。
沈天吉，「生態調洪池處理工業區非點源污染之研究」，國立成功大學碩士論文，2001。
潘豪龍，「以接觸氧化渠法處理受污染的排水路之研究」，國立成功大學碩士論文，2000。
許慶文，「竹塹的海濱植物」，竹塹文化資產叢書出版社，1998。

英文部分
Austin Elizabeth R., and G.Fred Lee, “Nitrogen release from lake sediments”, Journal WPCF Vol. 45, No. 5, 1973.
Dortch Mark S., Jeffrey A. Gerald, “Screening-level model for estimating pollutant removal by wetlands”, wetlands research program technical report WRP-CP-9, 1995.
Faulkner, S.P., and C.J., Richardson, “Physical and chemical characteristics of freshwater wetland soils, in constructed wetlands for wastewater treatment”, D.A.Hammer, ed., Lewis Publishers, Chelsea, Michigan, pp.41-72, 1989.
Gambrell, R.P., and W.H.Patrick, Jr., ”Chemical and microbiological properties of anaerobic soils and sediments, in Plant Life in Anaerobic Environments”, D.D.Hook and R.M.M.Crawford, eds., Ann Arbor Sci. pub. Inc., Ann Arbor, Mich., pp.375-423., 1978.
Gerke Sara,Lawrence A.Baker and Ying Xu, ”Nitrogen transforamtions in a wetland receiving lagoon effluent: sequential model and implications for water reuse”, Wat.Res.Vol.35, No.16, pp3857-3866, 2001.
Heliotis, F.D. and DeWitt, C.B. “A conceptual model of nutrient cycling in wetlands used for wastewater treatment : a literature analysis.” Wetlands, 3, pp.134-152, 1995.
Jing, S.R., Y.F.Lin, T.W.Wang, and D.Y.Lee. “Microcosm wetlands for wastewater treatment with different hydraulic loading rates and macrophytes” Journal of Environment Quality Vloume 31, no. 2, Mar.-Apr. 2002.
Kim Eastlick, “A primer on constructed wetlands course notes for evds”, 1999.
Liao, S.L., “An experimental evaluation of using construction wetlands for controlling stormwater pollution.” university of virginia, charlottesville, 1996.
Martin-EH, “Effectiveness and an urban runoff detention pond wetlands system”, J. of Environment Engineering, Vol. 114, Iss 4, pp.810-827, 1988.
Mohanty, S.K., and R.N.Dash, “The chemistry of waterlogged soils”, in wetlands－Ecology and Management, B.Gopal, R.E.Turner, R.G.Wetzel, and D.F.Whigham, eds., Natural Institute of Ecology and International Scientific Publications, Jaipur, India, pp.389-396, 1982.
Moreno-Grau S., A.García-Sánchez, j.Moreno-Clavel, J.Serrano-Aniorte, M.D.Moreno-Grau, “A mathematic model for waste water stabilization ponds with macrophytes and microphytes”, Ecological Modeling 91, pp.77-103, 1996.
Novotny Vladimir, and Olem Harvey, “Water Quality”, Van Nostrand Reinhold, 1994.
Odum, E.P., Funamentals of Ecology. 3rd. ed. W.B.Saundrs, 1971.
Peijl van der M.J., and J.T.A. Verhoeven, “A model of carbon, nitrogen and phosphorus dynamics and their interactions in river marginal wetlands“,Ecological Modelling 118, pp.95-130, 1999.
Reddy, K.R., and D.A.Graetz, “Carbon and nitrogen dynamics in wetland soils”, in: The Ecology and Management of Wetlands, vol. 1, D.D.Hook et al., eds., Timber Press, Portland, Ore., pp.307-318, 1988.
Spieles Douglas J., William J. Mitsch, “The effects of season and hydrologic and chemical loading on nitrate retention in constructed wetlands: a comparison of low- and high-nutrient riverine systems”, Ecological Engineering 14, pp 77-91, 2000.
Stelzer, R., and A.Lauchli, “Salt and flooding tolerance of Puccinellia peisonis, Ⅲ.Distribution and localization of ions in the plant”, Z.Pflanzenphysiol 88:437-448, 1978.
Theis, Thomas L., and Peter J.McCabe, “Phosphorus dynamics in hypereutrophic lake sediments”, Water Research Vol. 12. pp.677-685, 1978.
Thomann Robert V. and Mueller John A., “Principles of surface water quality modeling and control ”, Harper & Publishers, Inc., 1987.
Wang Naiming, William J.Mitsch, “A detailed ecosystem model of phosphorus dynamics in created riparian wetlands”, Ecological Modeling 126, pp.101-130, 2000.
Yang, Y., Z.Xu, K.Hu, J.Wang and G.Wang, “Removal efficiency of the constructed wetland wastewater treatment system at Bainikeng, Shenzhen” wetland systems for water pollution control, 1994.
Yu, S.L., Fitch, G.M., Earles, T.A., and Wolfe, D.D., “Constructed wetlands for nonpoint source pollution control.”, Report No. VTRC 99-R14, August 1998.

日文部分
宮宗 功「自然淨化機構」，技報堂出版株式會社，1990。
楠田 哲也 編著，「自然淨化機構強化制御」，技報堂出版株式會社，1994。