Integrating Treatment of Neutralization with Sulfidic Natural Water (SNW) to Capture Dissolved Copper (Cu 2+ ) from Acid Mine Drainage (AMD) at Batu Hijau Site, Sumbawa Island Indonesia

Surya Hadi; Ni Made Sri Suliartini; Lely Kurniawati; Surayyal Hizmi

doi:10.22146/ijc.28223

Integrating Treatment of Neutralization with Sulfidic Natural Water (SNW) to Capture Dissolved Copper (Cu²⁺) from Acid Mine Drainage (AMD) at Batu Hijau Site, Sumbawa Island Indonesia

https://doi.org/10.22146/ijc.28223

Surya Hadi^(1*), Ni Made Sri Suliartini⁽²⁾, Lely Kurniawati⁽³⁾, Surayyal Hizmi⁽⁴⁾

(1) Department of Chemistry, University of Mataram, Jl. Majapahit No. 62, Mataram-83125, Indonesia
(2) Department of Chemistry, University of Mataram, Jl. Majapahit No. 62, Mataram-83125, Indonesia
(3) Department of Chemistry, University of Mataram, Jl. Majapahit No. 62, Mataram-83125, Indonesia
(4) Department of Chemistry, University of Mataram, Jl. Majapahit No. 62, Mataram-83125, Indonesia
(*) Corresponding Author

Abstract

The overall objectives of the research were (1) to study the capability of sodium hydrosulfide (NaHS) and sulfidic natural water (SNW) of Sebau in recovery of Cu²⁺, (2) to investigate the potency of integrating treatments of neutralization with sulfidization using SNW of Sebau in removing Cu²⁺ from acid mine drainage (AMD) collected from Batu Hijau site. The first objective was achieved by separately reacting (in situ) NaHS and SNW with a Cu²⁺ solution at pH 5.5. The second objective was answered by conducting treatments of lime-neutralization by the use of three levels of pH (4.0; 5.5; 7.0) and sulfidization using SNW collected from Sebau, Lombok Island at three sampling points. The result showed that NaHS (61.6 mg/L) could precipitate Cu²⁺ solution (44.45 mg/L) up to 71.3%, while SNW of Sebau could precipitate Cu²⁺ solution (44.45 mg/L) for almost 100% at pH 5.5. The results also revealed that SNW could precipitate the remained Cu²⁺ in the AMD from the neutralization treatment (pH 4 = 113.5 mg/L; pH 5.5 = 85.01 mg/L; and pH 7.0 = 2.372 mg/L) to 83.84% (pH = 4.0) and 100% (pH = 5.5 and 7.0). Although both pH 5.5 and 7.0 could completely precipitate Cu²⁺ in the AMD, by comparing the experimental result with the stoichiometric analysis, it was predicted that pH 5.5 was an optimum pH level for the reaction between AMD and SNW to recover Cu²⁺ in the AMD. Without neutralization treatment, SNW showed potentiality to recover Cu²⁺ since the combination treatments of neutralization at pH 4 with SNW collected from three sample points resulted in a high percent recovery of Cu²⁺.

Keywords

acid main drainage (AMD); sulfidic natural water

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DOI: https://doi.org/10.22146/ijc.28223

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