Constructed wetlands review
Vol 3, Issue 1, 2020
VIEWS - 582 (Abstract) 489 (PDF)
Abstract
Natural water purification system especially constructed has been commonly employed in Taiwan and worldwide nowadays. This paper has reviewed several papers written by the author.
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1. Nurminen L, Horppila J. Life form dependent impacts of macrophyte vegetation on the ratio of resuspended nutrients. Water Research 2009; 43(13): 3217–3226.
2. Sinistro R, Sánchez ML, Marinone C, et al. Experimental study of the zooplankton impact on the trophic structure of phytoplankton and the microbial assemblages in a temperate wetland (Argentina). Limnologica 2007; 37: 88–99.
3. Melian C, Bascompte J, Jordano P, et al. Diversity in a complex ecological network with two interaction types. Oikos 2009; 118(1): 122–130.
4. Southichak B, Nakano K, Nomura M, et al. Phragmitesaustralis: a novel biosorbent for the removal of heavy metals from aqueous solution. Water Research 2006; 40: 2295–2302.
5. Mitsch WJ, Zhang L, Anderson CJ, et al. Creating riverine wetlands: ecological succession, nutrient retention, and pulsing effects. Ecological Engineering 2005; 25: 510–527.
6. Yeh TY. Pollutant removal within hybrid constructed wetland in tropical regions. Water Science and Technology 2009; 59(2): 233–240.
7. Yeh TY. Heavy metal removal within pilot-scale constructed wetlands receiving river water contaminated by confined swine operations. Desalination 2009; 249(1): 368–373.
8. Yeh TY. A study and analysis on the physical shading effect of water quality control in constructed wetlands. Journal of Environmental Protection 2014.
9. Kuo CT, Jan LY, Jan YN. Dendrite-specific remodeling of Drosophila sensory neurons requires matrix metalloproteases, ubiquitin-proteasome, and ecdysone signaling. Proceedings of the 10. National Academy of Sciences of the United States of America 2005; 102(42): 15230–15235.
10. Yeh TY. Causes of fish kill in a natural water purification system. International Journal of Environmental Science and Technology 2014; 3(9).
11. Yeh TY. Organic matter and nitrogen removal within field-scale constructed wetlands: Reduction performance and microbial identification studies. Water Environmental Research 2010; 82(1): 27–33.
12. Molle F, Mollinga PP, Meinzen-Dick R. Water, politics and development: Introducing water alternatives. Water Alternatives 2008; 1(1): 1–6.
13. Mayo AW, Bigambo T. Nitrogen transformation in horizontal surface flow constructed wetland I: Model development. Physics and Chemistry of the Earth 2005; 30: 658–667.
14. Kadlec RH, Knight RL. Treatment wetlands. Boca Raton: Lewis Publishers; 1996. p. 893.
15. Park SW, Kuroda MI, Park Y. Regulation of histone H4 Lys16 acetylation by predicted alternative secondary structures in roX noncoding RNAs. Molecular and Cellular Biology 2008; 28(16): 4952–4962.
16. Vymazal J. Removal of nutrients in various types of constructed wetlands. Science of the Total Environment 2007; 380: 48–65.
17. Gottschall N, Boutin C, Crolla A, et al. The role of plants in the removal of nutrients at a constructed wetland treating agricultural (dairy) wastewater, Ontario, Canada. Ecological Engineering 2007; 29(2): 154–163.
18. Wang Y, Xu Z, Bach SJ, et al. Effects of phlorotannins from Ascophyllum nodosum (brown seaweed) on in vitro ruminal digestion of mixed forage or barley grain. Animal Feed Science and Technology 2008; 145(1/4): 375–395.
DOI: https://doi.org/10.24294/sf.v3i1.960
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