Ability of Humic Acid in the Absorption of Heavy Metal Content of Lead and Iron in Fish Culture Media

Kiswanto; Wintah

doi:10.12911/22998993/161328

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Tytuł artykułu

Ability of Humic Acid in the Absorption of Heavy Metal Content of Lead and Iron in Fish Culture Media

Autorzy

Kiswanto , Wintah

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DOI

10.12911/22998993/161328

Warianty tytułu

Języki publikacji

Abstrakty

The young coal mining pits (young pits) found in West Aceh cause many problems. These pits that form ponds have the potential to be utilized for aquaculture activities. However, the main problem faced in the young pits is the high content of heavy metals. This makes the ponds dangerous for fish farming. Hazardous heavy metals in coal mines are Pb and Fe. Humic acid is one of the materials that can be used to minimize heavy metals and increase water pH. The use of humic acid is more efficient because this technology is easy and cheap and the raw materials are abundant. Humic acid acts as a substance of cation exchange ability found in compost. This research has a long-term goal of making humic acid contained in compost as an alternative material that can minimize heavy metals Pb and Fe, so that it can be used for fish farming activities. The specific objective is to determine the best capacity (dose of humic acid) in minimizing heavy metals and increasing the pH of young pond water in former mines and its effect on fish farming. This research method used a completely randomized design consisting of one factor, namely the dose of humic acid (0 g/L, 2.5 g/L, 5 g/L, 7.5 g/L) and three replications. The results showed that humic acid was able to minimize the content of heavy metals Pb and Fe in coal mine water with the best dose of 5 g/L. The percentage reduction produced was more than 90%. The results of fish rearing using ex-mining pond water treated with humic acid showed that the survival rate and growth rate of fish were higher.

Słowa kluczowe

humic acid heavy metals fish farming media

Wydawca

Polskie Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology

Czasopismo

Journal of Ecological Engineering

Rocznik

2023

Tom

Vol. 24, nr 5

Strony

95--102

Opis fizyczny

Bibliogr. 34 poz., tab.

Twórcy

autor

Kiswanto

kiswanto@utu.ac.id

Faculty of Health Sciencee, University of Teuku Umar, Alue Peunyareng St, Ujong Tanoh Darat, Meureubo, West Aceh District, Aceh 23681, Indonesia

https://orcid.org/0000-0002-5639-0146

autor

Wintah

Faculty of Health Sciencee, University of Teuku Umar, Alue Peunyareng St, Ujong Tanoh Darat, Meureubo, West Aceh District, Aceh 23681, Indonesia

Bibliografia

1. Adhiatma, S., Susanto, T.B., Nurmiyanto, A. 2014. Application of Ameliorant Materials (Humic Acid; Coal Mining IPAL Sludge) on Reclamation Plant Growth on Ex-Coal Mining Land, 6, 26–37
2. Ahalya, N., Ramachandra, T.V., Kanamadi, R.D. 2003 Review paper: Biosorption of heavy metals. Research Journal Of Chemistry And Environment, 7(4), 71–79.
3. Atik Rahmawati, S.J.S. 2012. Study Of Pb(Ii) And Cd(Ii) Metal Adsorption On Humic Acid In Water Medium, 22, 2(1).
4. Hafids, R., Pagoray, H. 2015. Heavy Metal Content of Fe and Mn in Fish Cultured in Post Coal Mining Pond at Kutai Kartanegara Regency, East Kalimantan, 21(1), 61–67.
5. Hermana, J., Nurhayati, E. 2010. Removal of Cr3+ and Hg2+ using compost derived from municipal solid waste. Sustainable Environment Research, 20(4), 257–261.
6. Triswiyana, I., Permatasari, A., Kurniawan, A. 2019 Utilization of Ex Tin Mine Lake For Aquaculture: Case Study Of Muntok Sub District, West Bangka Regency. Samakia: Jurnal Ilmu Perikanan, 10(2), 99–104. https://doi.org/10.35316/jsapi.v10i2.534
7. Ismail, I., Moustafa, T. 2016. Biosorption of heavy metals. Heavy Metals: Sources, Toxicity and Remediation Techniques, January 2016, 131–174.
8. Kiswanto, Susanto, H., Sudarno. 2018a. Characterization of Coal Acid Water in Void Pools of Coal Mining in South Kalimantan. E3S Web of Conferences, 73. https://doi.org/10.1051/e3sconf/20187305030
9. Kiswanto, Susanto, H., Sudarno. 2018b Characteristics of Acid Coal Water in Ex-Coal Mining Ponds of PT. Bukit Asam (PTBA). IDEC National Seminars And Conferences, 7–8.
10. Kiswanto, Susanto, H., Sudarno. 2020. Treatment of coal mine acid water using NF270 membrane as environmentally friendly technology. Jurnal Pendidikan IPA Indonesia, 9(3), 439–450. https://doi.org/10.15294/jpii.v9i3.23310
11. Kiswanto, Susanto, H., Sudarno, Wintah. 2021 NF270 membrane technology: New-product from acid mine drainage. Journal of Green Engineering, 11(1), 807–823.
12. Kiswanto, Wintah, Rahayu, N.L. 2020 Analysis Of Heavy Metals (Mn, Fe, Cd), Cyanide And Nitrite In Acid Water Coal Mining. Pekalongan City Research and Development Journal, 18, 20–26.
13. Kiswanto, Wintah, Sriwahyuni, S., Nurdin. 2022. Post-mining pond water suitability for fisheries culture in West Aceh, Indonesia. AACL Bioflux, 15(1), 436–445.
14. Kumar, N. 2016. Ground Water Contamination in Coal Mining Areas: A Critical Review. International Journal of Engineering and Applied Sciences, 3(2), 69–73.
15. Kurniawan, A. 2017. Chronosequence Effect of Post Tin Mining Ponds to Metals Residu and Microecosystem Change. Omni-Akuatika, 13(1). https://doi.org/10.20884/1.oa.2017.13.1.153
16. Lambregts, B., Zonneveld, W. 2004 From Randstad to Deltametropolis: Changing attitudes towards the scattered metropolis. European Planning Studies, 12(3), 299–321. https://doi.org/10.1080/0965431042000195056
17. Lasmi, L. 2016. Humat Competitive Adsorption Study Of Ag ( I ) And Cr ( Iii ) On Humic Acid Indonesia is a country that has a large enough peat potential. Indonesia is ranked fourth in the world with an area of about 20.6 million, 1(2), 80–92.
18. Maidie, A., Udayana, D., Almady, I.F., Susanto, A., Sukarti, K., Manege, I., Mulawarman, U., Kelua, K.G. 2010. Utilization of coal mine settling ponds for local fish farming in cages, 437–448.
19. Meyzilia, A. 2018 Utilization of Water Under the Former Tin Mine as an Additive to Groundwater Using Compost Pit in Bangka Belitung. Journal of Social Science Education, 27(1), 22–30.
20. Meyzilia, A., Darsiharjo. 2017 Utilization of Ex-Tin Mine Excavations. Journal of Geographical Education, 17(2), 153–158.
21. Mindari, W., Aini, N., Kusuma, Z. 2014. Effects of humic acid-based buffer + cation on chemical characteristics of saline soils and maize growth. Journal of Degraded and Mining Lands Management, 2(1), 259–268. https://doi.org/10.15243/jdmlm.2014.021.259
22. Nane, L. 2019. Subject: Fisheries Biology. Practical Guidebook for Fisheries Biology Courses, Faculty of Fisheries and Marine Sciences, State University of Gorontalo, 17.
23. Noor, S.F.M., Ahmad, N., Khattak, M.A., Mukhtar, A., Badshah, S., Khan, R.U. 2019 Removal of Heavy Metal from Wastewater: A Review of Current Treatment Processes, 1(1), 1–9.
24. Pitulima, J. 2016. Water Resource Suitability Evaluation of Any Contaminant Pond Mining Tailing from Tin Ore Remaining Activity in Bangka Island, 4(December), 38–43.
25. Prasetiyono, E. 2015. Ability of Compost in Reducing Content of Lead Heavy Metal (Pb) in Fish Farming Media. Compost Ability in Reducing Content of Lead Heavy Metal in Fish Farming Culture Media. Journal of Aquatics, 1, 21–29.
26. Prasetiyono, E., Syaputra, D. 2018. In Perpat Permai Fish Cultivation Group, Kelurahan. LPM News, 21(2).
27. Prasetiyono, E.V.A. 2012. The Use Of Compost To Minimize The Content Of Heavy Metal, Black Tin (Pb) In Fish Cultivation Media. IPB.
28. Rahman, M.T., Khan, A.H., Negash, B.M., Sultana, K., Hasan, M.A., Askary, A., Rubbi, F., Das, L., 2021. Effects of Disposed-water from Barapukuria Coal Mine, Dinajpur, Bangladesh on Agriculture and Aquaculture. IOP Conference Series: Materials Science and Engineering, 1176(1), 012008. https://doi.org/10.1088/1757-899x/1176/1/012008
29. Septiani, U., Tasari, F.J. 2020. Humic Acid Adsorption on Natural Zeolite Modified with TiO 2, 11(1), 43–51.
30. Setiawan, A.A., Budianta, D., Suheryanto, S., Priadi, D.P. 2018. Review: Pollution due to Coal Mining Activity and its Impact on Environment. Sriwijaya Journal of Environment, 3(1), 1–5. https://doi.org/10.22135/sje.2018.3.1.1-5
31. Talukdar, B., Das, J., Kalita, H.K., Basumatary, S. 2016. Impact of Open Cast Coal Mining on Fish and Fisheries of Simsang River, Meghalaya, India. Journal of Marine Science: Research & Development, 6(6). https://doi.org/10.4172/2155-9910.1000214
32. Urbasa, P.A., Undap, S.L., Rompas, R.J. 2019. Impact of Water Quality on Fish Cultivation with Plugin Nets in Toulimembet Village, Lake Tondano. E-Journal of Water Culture, 3(1), 59–67. https://doi.org/10.35800/bdp.3.1.2015.6932
33. Yadav, H.L., Jamal, A. 2018. Assessment of water quality in coal mines: A quantitative approach. Rasayan Journal of Chemistry, 11(1), 46–52. https://doi.org/10.7324/RJC.2018.1111961
34. Yuliyati, Y.B., Nathanael, C.L., Chemistry, J., Mathematics, F., Nature, P. 2016. Isolation Of Humic Acid Characterization And Determination Of Its Absorption To Metal Ions Pb (Ii) Cu (Ii) And Fe (Ii). 4(2), 43–53.

Uwagi

Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).

Typ dokumentu

Bibliografia

Identyfikator YADDA

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