Analysis of Water Plant Utilization using Organic Substrate Combinations to Manage COD BOD Turbidity in Pit Lak

Indun Titisariwati, Hadi Oetomo, Muhammad Tri Aditya, Waterman Sulistyana Bargawa

Abstract


Because of changing the physicochemical conditions of the water, the pit lake of the quarry feldspar has the potential to pollute the environment. The parameter values of COD, BOD, and turbidity in contaminated mine water are not according to quality standards. This research is water management with plant media in pit lake using a passive remediation method. The purpose of this study was to determine the ability to use Eichornia sp and Thypa Angustifolia plants using a combination of organic substrates in managing turbidity, COD, and BOD in post-mining feldspar water. This research is an experimental method by making a research reactor. There were six tubs with different treatments in each tub, treatment one as control, namely water, and MaterialMaterial in the pit lake; treatment 2 added organic substrate, treatment three added Thypa Angustifolia plants, treatment 4 added Thypa Angustifolia plants and organic substrate, treatment five added plants Eichornia sp, treatment six was added with Eichornia sp plants and organic substrate. The amount of water in each treatment is 350 liters, the pit lake material is 20 kg, and the organic substrate is 4 kg and the residence time is 15 days. Sampling was carried out every three consecutive days. The results showed that Thypa Angustifolia plants with a combination of organic substrates were able to reduce the turbidity value, while Eichornia sp plants using a combination of organic substrates could efficiently reduce COD and BOD values.


Keywords


Pit lake, Plants, Organic Substrate, Turbidity, COD, BOD

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K.H. Low, I.B. Koki, H. Juahir, A. Azid, S. Behkami, R. Ikram, H.A. Mohammed, S.M. Zain., 2016. Evaluation of water quality variation in lakes, rivers, and ex-mining ponds in Malaysia (review), Desal. Wat. Treat., 57 (2016) 28215–28239.

Bargawa, W.S., Panca, A., Andiani, H,F., 2019, Design of Mine Drainage Systems in Coal Mine, E3S Web of Conferences 76, 04006, p. 1-6.

Bargawa, W.S. 2017, Sustainable and Contextual Utilization of Underground River in the Arid Area, Environmental and Earth Science Symposium, 3th International Conference on Science and Technology (ICST) UGM.

Soni, A.K., Mishra, B., Singh, S., 2014. Pit lakes as an end use of mining: A review. J. Min. Environ. 5 (2), 99–111.

Bargawa, W.S., 2017, Reklamasi dan Pascatambang, Prodi Teknik Pertambangan, UPN “Veteran”, Yogyakarta. (in Indonesia)

Pal S, Mukherjee AK, Senapati T, Samanta P, Mondal S, Ghosh AR. Surface water quality assessment of abandoned opencast coal pit-lakes in Raniganj coalfields area, India. The Ecoscan 2013; Special issue, Vol. IV: 175-188.

Migaszewski, Z.M., Galuszka, A., Dolegowska, S., 2018. Arsenic in the Wiśniówka acid mine drainage area (south-central Poland)–Mineralogy, hydrogeochemistry, remediation. Chem. Geol. 493, 491–503.

Muthusaravanan, S., Sivarajasekar, N., Vivek, J.S. et al., 2018. Phytoremediation of heavy metals: mechanisms, methods and enhancements Environ. Chem. Lett., 16 (4), pp. 1339-1359

Sricoth, T., Meeinkuirt, W., Pichtel, J. et al., 2018. Synergistic phytoremediation of wastewater by two aquatic plants (Typha angustifolia and Eichhornia crassipes) and potential as biomass fuel. Environ Sci Pollut Res 25, 5344–5358. https://doi.org/10.1007/s11356-017-0813-5

Newcombe,CE, Brennan RA.,2010. Improved passive treatment of acid mine drainage in mushroom compost amended with crab-shell chitin. J Environ Eng 136:616–626

McCullough, C.D.; Vandenberg, J.A, 2020. Studying Mine Pit Lake Systems across Multiple Scales. Mine Water and the Environment https://doi.org/10.1007/s10230-020-00678-7

Ashraf, M. A.; Maah, M. J.; Yusoff, I., 2010. Study of water quality and heavy metals in soil and water of ex-mining area Bestari Jaya, Peninsular Malaysia, Int. J. Basic. Appl. Sci., 10(3), 7– 27 (21 pages).

S.S. Mohammed, 2015. Effect of pH on the Turbidity Removal of Wastewater, Vol.02 No.12. Article ID:69015, 9 pages10.4236/oalib.1102283 https://doi.org/10.4236/oalib.1102283.

W. Boyles, 1997. The Science of Chemical Oxygen Demand, Technical Information Series, Booklet No. 9, Hach Company, Loveland, CO, USA.

Geerdink, R.B.; van den Hurk, R.S.; Epema, O.J., 2017. Chemical oxygen demand: Historical perspectives and future challenges. Anal. Chim. Acta, 961, 1-11.

Penn MR, Pauer JJ, Mihelcic JR ,2006. Biochemical oxygen demand. In: Sabljic A (ed) Environmental and ecological chemistry. Encyclopedia of Life Support Systems (EOLSS), Eolss Publishers, Oxford

Jouanneau, S., Recoules, L., Durand, M.J., Boukabache, A., Picot, V., Primault, Y., Lakel, A., Sengelin, M., Barillon, B., Thouand, G., 2014. Methods for assessing biochemical oxygen demand (BOD): a review. Water Res. 49, 62e82

Favas, P.J.; Pratas, J.; Varun, M.; D’Souza, R.; Paul, M.S, 2014. Phytoremediation of soils contaminated with metals and metalloids at mining areas: Potential of native flora. In Environmental Risk Assessment of Soil Contamination; Maria, C., Hernandez, S., Eds.; InTech: Shanghai, China.

Chatterjee, S.; Datta, S.; Halder, M.P.; Mitra, A.; Veer, V.; Mukhopadhyay, S.K, 2013. Use of wetland plants in bioaccumulation of heavy metals. In Plant-Based Remediation Processes; Gupta, D.K., Ed.; Springer: Berlin, Heidelberg, Germany, ; pp. 117–139.

G.J. Zagury, V. Kulnieks, C.M. Neculita, 2006. Characterization and reactivity assessment of organic substrates for sulfate reducing bacteria in acid mine drainage treatment, Chemosphere 64 944–954.

Zawani, Z., Chuah-Abdullah, L., Ahmadun, F.-R., Abdan, K., 2013. Acclimatization process of microorganisms from activated sludge in kenaf-retting wastewater. Developments in Sustainable Chemical and Bioprocess Technology. Springer, pp. 59–64.

Wilson JRU, Richardson DM, Rouget M, et al., 2007. Residence time and potential range: crucial considerations in plant invasion ecology, Diversity and Distributions, vol. 13 (pg. 11-22)




DOI: https://doi.org/10.31098/ess.v1i1.112

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