PL EN


Preferencje help
Widoczny [Schowaj] Abstrakt
Liczba wyników
Tytuł artykułu

Kinetics of Phosporus Removal from Laundry Wastewater in Constructed Wetlands with Equisetum hymale

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The objective of this study was to determine the capacity, process, and kinetics of phosphorus (PO4-P) nutrients pollutant removal in constructed wetlands with Equisetum hymale plants. This research was conducted by using a batch system constructed wetlands with detention time variation of 1–5 days and using gravel, sand, and soil as the media. The laundry wastewater used for this research was collected from commercial activity in Surabaya city. The results of this research showed that the removal efficiency of PO4-P using the constructed wetlands with Equisetum hymale was between the range of 95.49–99.43%. The removal process was done by screening-adsorption, and the sedimentation mechanisms from the media, and the biosorpsion by the plants was shown by the increasing content of PO4-P in soil and plants, which amounted to 14.80% and 9.23% respectively. The removal kinetics of PO4-P was according to the second-order model with value of R2 = 0.99.
Słowa kluczowe
Rocznik
Strony
60--65
Opis fizyczny
Bibliogr. 22 poz., rys., tab.
Twórcy
  • Study Program of Environmental Engineering, Faculty Science and Technology, Universitas Airlangga, Surabaya 60115, Indonesia
  • Study Program of Environmental Engineering, Faculty Science and Technology, Universitas Airlangga, Surabaya 60115, Indonesia
  • Study Program of Biology, Faculty Science and Technology, Universitas Airlangga, Surabaya 60115, Indonesia
Bibliografia
  • 1. Abdolzadeh, A., Wang, X., Veneklaas, E.J., Lambers, H., 2010. Effects of phosphorus supply on growth, phosphate concentration and cluster-root formation in three Lupinus species. Annals of Botany. vol. 105, 365–374.
  • 2. Adnan, F., Thanasupsin, S.P., 2016. Kinetic studies using a linear regression analysis for a sorption phenomenon of 17a-methyltestosterone by Salvinia cucullata in an active plant reactor. Environmental Engineering Research. vol. 21, 384–392.
  • 3. APHA, 2012. Standard Methods for the Examination of Water and Wastewater, 21th ed. American Public Health Association, Washington DC, USA.
  • 4. Di Luca, G.A., Maine, M.A., Mufarrege, M.M., Hadad, H.R., Pedro, M.C., Sánchez, G.C., Caffaratti, S.E., 2017. Phosphorus distribution pattern in sediments of natural and constructed wetlands. Ecological Engineering. vol. 108, 227–233.
  • 5. Farzadkia, M., Ehrampush, M.H., Mehrizi, E.A., Sadeghi, S., Talebi, P., Salehi, A., Kermani, M., 2015. Investigating the efficiency and kinetic coefficients of nutrient removal in the subsurface artificial wetland of Yazd wastewater treatment plant. Environmental Health Engineering and Management Journal. vol. 2, 23–30.
  • 6. Ghosh, D., Gopal, B., 2010. Effect of hydraulic retention time on the treatment of secondary effluent in a subsurface flow constructed wetland. Ecological Engineering. vol. 36, 1044–1051.
  • 7. Gupta, P., Ann, T.W., Lee, S.M., 2016. Use of biochar to enhance constructed wetland performance in wastewater reclamation. Environmental Engineering Research. vol. 21, 36–44.
  • 8. Jóźwiakowski K., Bugajski P., Kurek K., de Carvalho M., Almeida M.A., Gajewska M., Siwiec T., Borowski G., Czekała W., Dach J., Gajewska M. 2018. The efficiency and technological reliability of biogenic compounds removal during long-term operation of a one-stage subsurface horizontal flow constructed wetland. Separation and Purification Technology. vol. 202, 216–226.
  • 9. Le Moal, M., Gascuel-Odoux, C., Ménesguen, A., Souchon, Y., Étrillard, C., Levain, A., Moatar, F., Pannard, A., Souchu, P., Lefebvre, A., Pinay, G., 2019. Eutrophication: A new wine in an old bottle? Science of The Total Environment. vol. 651, 1–11.
  • 10. Meng, P., Pei, H., Hu, W., Shao, Y., Li, Z., 2014. How to increase microbial degradation in constructed wetlands: Influencing factors and im provement measures. Bioresource Technology. vol 157, 316–326.
  • 11. Merino-Solís, M., Villegas, E., de Anda, J., LópezLópez, A., 2015. The Effect of the Hydraulic Retention Time on the Performance of an Ecological Wastewater Treatment System: An Anaerobic Filter with a Constructed Wetland. Water. vol. 7, 1149–1163.
  • 12. Olguín, E.J., Sánchez-Galván, G., Melo, F.J., Hernández, V.J., González-Portela, R.E., 2017. Long-term assessment at field scale of Floating Treatment Wetlands for improvement of water quality and provision of ecosystem services in a eutrophic urban pond. Science of The Total Environ. vol. 584–585, 561–571.
  • 13. Pérez, M.M., Hernández, J.M., Bossens, J., Jiménez, T., Rosa, E., Tack, F., 2014. Vertical flow constructed wetlands: Kinetics of nutrient and organic matter removal. Water Science and Technolohy. vol. 70, 76–81.
  • 14. Ramprasad, C., Smith, C.S., Memon, F.A., Philip, L., 2017. Removal of chemical and microbial contaminants from greywater using a novel constructed wetland: GROW. Ecological Engineering. vol. 106, 55–65.
  • 15. Sirianuntapiboon, S., Kongchum, M., Jitmaikasem, W., 2006. Effects of hydraulic retention time and media of constructed wetland for treatment of domestic wastewater. Journal of Agricultural Research. vol. 1, 27–37.
  • 16. Smith, F.W., 2002. The phosphate uptake mechanism. Plant and Soil. vol. 245, 105–114.
  • 17. Timotewos, M.T., Kassa, K., Reddythota, D., 2017. Selection of mesocosm to remove nutrients with constructed wetlands. Journal of Ecological Engineering. vol. 18, 42–51.
  • 18. Vymazal, J., 2014. Constructed wetlands for treatment of industrial wastewaters: A review. Ecological Engineering. vol. 73, 724–751.
  • 19. Wu, H., Zhang, J., Ngo, H.H., Guo, W., Hu, Z., Liang, S., Fan, J., Liu, H., 2015. A review on the sustainability of constructed wetlands for wastewater treatment: Design and operation. Bioresource Technology. vol. 175, 594–601.
  • 20. Yeh, N., Yeh, P., Chang, Y.H., 2015. Artificial floating islands for environmental improvement. Renewable and Sustainable Energy Reviews. vol. 47, 616–622.
  • 21. Zhang, D.Q., Jinadasa, K.B.S.N., Gersberg, R.M., Liu, Y., Ng, W.J., Tan, S.K., 2014. Application of constructed wetlands for wastewater treatment in developing countries – A review of recent developments (2000–2013). Journal of Environmental Management. vol. 141, 116–131.
  • 22. Zhu, W.L., Cui, L.H., Ouyang, Y., Long, C.F., Tang, X.D., 2011. Kinetic Adsorption of Ammonium Nitrogen by Substrate Materials for Constructed Wetlands. Pedosphere. vol.21, 454–463.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-08621af4-3cfd-4458-b4b7-78741a48e23a
JavaScript jest wyłączony w Twojej przeglądarce internetowej. Włącz go, a następnie odśwież stronę, aby móc w pełni z niej korzystać.