Acid Mine Drainage Neutralization Effort in Mud Media by Lactobacillus casei Bacteria and Dekkera bruxellensis Fungi

Apramadha, Made Sandra; Rinanti, Astri; Ratnaningsih; Minarti, Astari; Aphirta, Sarah; Rahmiyati, Lutfia; Marendra, Sheilla Megagupita Putri; Sunaryo, Thalia

doi:10.12911/22998993/166556

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Tytuł artykułu

Acid Mine Drainage Neutralization Effort in Mud Media by Lactobacillus casei Bacteria and Dekkera bruxellensis Fungi

Autorzy

Apramadha Made Sandra , Rinanti Astri , Ratnaningsih , Minarti Astari , Aphirta Sarah , Rahmiyati Lutfia , Marendra Sheilla Megagupita Putri , Sunaryo Thalia

Treść / Zawartość

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DOI

10.12911/22998993/166556

Warianty tytułu

Języki publikacji

Abstrakty

Mine acid drainage (MAD) is a primary environmental problem caused by mining activity. The main characteristics of MAD are extremely low pH level (1.5–4.0), as well as content of sulfate and a number of heavy metals and metalloids that can destroy vegetation, accelerate erotion, and disrupt land ecosystem balance. The objective of this research was to process MAD by improving pH level and lowering iron and manganese content in MAD by Lactobacillus casei and Dekkera bruxellensis mixed culture. MAD Neutralization test was conducted on SMSs media with MAD concentration variations of 10, 15, 20 and 25 (%;v/v), and contact time variations of 48, 96, 144, and 192 (hours). The MAD neutralization test by Lactobacillus casei and Dekkera bruxellensis mixed culture occurred best at 10% concentration (v/v) with contact time of 96 hours. The pH improvement reached up to 6.20 with iron metal efficiency removal at 32.47% and manganese metal up to 24.94%. MAD neutralization test revealed that the best contact time variation is at 96 hours. At this contact time, the pH level was increased to 6.17 with iron metal removal efficiency at 31.17% and manganese metal removal at 25.43%.

Słowa kluczowe

mine acid drainage neutralisation iron removal manganese removal Lactobacillus casei Dekkera bruxellensis

Wydawca

Polskie Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology

Czasopismo

Journal of Ecological Engineering

Rocznik

2023

Tom

Vol. 24, nr 8

Strony

277--286

Opis fizyczny

Bibliogr. 29 poz., rys., tab.

Twórcy

autor

Apramadha Made Sandra

Environmental Engineering, Faculty of Lanscape Architecture and Environmental Technology, Trisakti University, West Jakarta 11440, DKI Jakarta, Indonesia

autor

Rinanti Astri

astririnanti@trisakti.ac.id

Environmental Engineering, Faculty of Lanscape Architecture and Environmental Technology, Trisakti University, West Jakarta 11440, DKI Jakarta, Indonesia

https://orcid.org/0000-0001-8649-6307

autor

Ratnaningsih

Environmental Engineering, Faculty of Lanscape Architecture and Environmental Technology, Trisakti University, West Jakarta 11440, DKI Jakarta, Indonesia

autor

Minarti Astari

Environmental Engineering, Faculty of Lanscape Architecture and Environmental Technology, Trisakti University, West Jakarta 11440, DKI Jakarta, Indonesia

https://orcid.org/0000-0003-2641-7907

autor

Aphirta Sarah

Environmental Engineering, Faculty of Lanscape Architecture and Environmental Technology, Trisakti University, West Jakarta 11440, DKI Jakarta, Indonesia

https://orcid.org/0000-0003-4213-2004

autor

Rahmiyati Lutfia

Environmental Engineering, Faculty of Lanscape Architecture and Environmental Technology, Trisakti University, West Jakarta 11440, DKI Jakarta, Indonesia

autor

Marendra Sheilla Megagupita Putri

Environmental Engineering, Faculty of Lanscape Architecture and Environmental Technology, Trisakti University, West Jakarta 11440, DKI Jakarta, Indonesia

autor

Sunaryo Thalia

Environmental Engineering, Faculty of Lanscape Architecture and Environmental Technology, Trisakti University, West Jakarta 11440, DKI Jakarta, Indonesia

Bibliografia

1. Abinandan, S., Perera, I.A., Subashchandrabose, S.R., Venkateswarlu, K., Cole, N., Megharaj, M. 2020. Acid-adapted microalgae exhibit phenotypic changes for their survival in acid mine drainage samples. FEMS Microbiology Ecology, 96(11), 1–12.
2. Blomqvist, J. 2011. Dekkera bruxellensis – A competitive yeast for ethanol production from conventional and non-conventional substrates. Doctoral Thesis, Swedish University of Agricultural Sciences.
3. Bwapwa, J.K., Jaiyeola, A.T., Chetty, R. 2017. Bioremediation of acid mine drainage using algae strains: A review. South African Journal of Chemical Engineering, 24, 62–70.
4. Ávila, P.F., Silva, E.F., Ferreira, A., Salgueiro, A.R.G.N.L., Teixeira, J.P. 2014. Acid mine drainage from the Panasqueira mine and its influence on Zêzere river (Central Portugal). Journal of African Earth Sciences, 99, 705–712.
5. Chan, W.K., Wildeboer, D., Garelick, H., Purchase, D. 2016. Mycoremediation of heavy metal/metalloid-contaminated soil: Current understanding and future prospects. Fungal Applications in Sustainable Environmental Biotechnology, 249–272.
6. Deng, X., Wang, P. 2012. Isolation of marine bacteria highly resistant to mercury and their bioaccumulation process. Bioresource Technology, 121, 342–347.
7. Dhir, B. 2018. Biotechnological tools for remediation of acid mine drainage (removal of metals from wastewater and leachate). Bio-Geotechnologies for Mine Site Rehabilitation, 67–82.
8. Dixit, R., Wasiullah, Malaviya, D., Pandiyan, K., Singh, U.B., Sahu, A., Shukla, R., Singh, B.P., Rai, J.P., Sharma, P.K., Lade, H., Paul, D. 2015. Bioremediation of heavy metals from soil and aquatic environment: an overview of principles and criteria of fundamental processes. Sustainability, 7, 2189–2212.
9. Favas, P.J.C., Sarkar, S.K., Rakshit, D., Venkatachalam, P., Prasad, M.N.V. 2016. Acid mine drainages from abandoned mines. Environmental Materials and Waste, 413–462.
10. Fomina, M., Gadd, G.M. 2014. Biosorption: current perspectives on concept, definition and application. Bioresource Technology, 160, 3–14.
11. Jamil, I.N., Clarke, W.P. 2013. Bioremediation for acid mine drainage: organic solid waste as carbon sources for sulfate-reducing bacteria: A review. Journal of Mechanical Engineering and Science, 5, 569–581.
12. Kanamarlapudi, S.L., Muddada, S. 2020. Biosorption of Iron (II) by Lactobacillus fermentum from aqueous solutions. Polish Journal of Environmental Studies, 29(2), 1659–1670.
13. Kumar, V., Dwivedi, S.K. 2021. Mycoremediation of heavy metals: processes, mechanisms, and affecting factors. Environtal Science and Pollution Research, 28, 10375–10412.
14. Okeke, M.N., Eze, P.C., Eze, C.N. 2019. Concentration of heavy metals in the soil and plants around waste dumpsites In Enugu Metropolis, Nigeria. Indonesian Journal of Urban and Environmental Technology, 3, 13–27.
15. Oves, M., Khan, M.S., Zaidi. 2013. A. Biosorption of heavy metals by Bacillus thuringiensis strain OSM29 originating from industrial effluent contaminated north Indian soil. Saudi Journal of Biological Science, 20(2), 121–129.
16. Pondja Jr., E.A., Persson, K.M. & Matsinhe, N.P. 2014. A Survey of Experience Gained from the Treatment of Coal Mine Wastewater. J. Water Resour. Prot., 6, 1646–1658.
17. Putri, A.N., Ratnaningsih, R., Rinanti, A. 2021. Acid mine drainage removal by mixed bacteria culture of Pseudomonas aeruginosa and Brevibacterium sp. IOP Conference Series: Earth and Environmental Science, 1098, 052072.
18. Qadir, A., Hashmi, M.Z., Mahmood, A. 2017. Xenobiotics, types, and mode of action. Xenobiotics in the Soil Environment, Soil Biology, 49, 1–7.
19. Rambabu, K., Banar, F., Pham, Q.M., Ho, S.H., Ren, N., Show, P.L. 2020. Biological remediation of acid mine drainage: Review of past trends and current outlook. Environtal Science Ecotechnology, 2, 100024.
20. Rinanti, A., Fachrul, M.F., Hadisoebroto, R., Silalahi M.D.S. 2018. Biosorption of Cu (II) by Scenedesmus Obliquus: Optimization in Phovasoli Haemotococcus Medium. Internasional Journal of Geomate, 15(52), 45–52.
21. Samal, D.P.K., Sukla, L.B., Pattanaik, A., Pradhan, D. 2020. Role of microalgae in treatment of acid mine drainage and recovery of valuable metals. Materials Today, 30, 346–350.
22. Sihotang, M.S.M., Rinanti, A., Fachrul, M.F. 2021. Heavy metal removal and acid mine drainage neutralization with bioremediation approach. IOP Conference Series: Earth and Environmental Science, 894, 012041.
23. Siwi, W.P., Rinanti, A., Silalahi, M.D.S., Hadisoebroto, R., Fachrul, M.F. 2018. Effect of biosorbent immobilized on the heavy metals Cu2+ biosorption with variations of temperature and initial concentration of waste. IOP Conference Series: Earth and Environmental Science, 106, 012113.
24. Śliżewska, K., Chlebicz-Wójcik, A. 2020. Growth kinetics of probiotic Lactobacillus strains in the alternative, cost-efficient semi-solid fermentation medium. Biology (Basel), 9(12), 423.
25. Verma, T.K. 2017. Removal of Fe(II) using Aspergillus flavus from aqueous solution. Indian J. Sci. Res., 13, 63–67.
26. Widyaningrum, D.A., Rinanti, A., Hadisoebroto, R. 2021. The kinetics of Fe 2+ heavy metal adsorption by microalgae Desmodesmus sp. beads. IOP Conference Series: Earth and Environmental Science, 894, 012040.
27. Wikaningrum, T., Hakiki, R., Astuti, M.P., Ismail, Y., Sidjabat, F.M. 2022. The eco enzyme application on industrial waste activated sludge degradation. Indonesian Journal of Urban and Environmental Technology, 5(2),115–133.
28. Wilan, T., Hadisoebroto, R., Rinanti, A. 2019. Coppper biosorption using beads biosorbent of mixed culture microalgae. Journal of Physics: Conference Series, 1402, 022110.
29. Ye, F., Gong, D., Pang, C., Luo, J., Zeng, Z., Shang, C. 2020. Analysis of fungal composition in mine-contaminated soils in hechi city. Current Microbiology, 77(10), 2685–2693.

Typ dokumentu

Bibliografia

Identyfikator YADDA

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