Evaluation of Efficiencies of Locally Available Neutralizing Agents for Passive Treatment of Acid Mine Drainage

Evaluation of Efficiencies of Locally Available Neutralizing Agents for Passive Treatment of Acid Mine Drainage

Acid mine drainage (AMD) generated from the mining industry elevates environmental concerns due to the pollution and contamination it causes to bodies of water. Over the years, passive treatment of AMD using alkalinity-generating materials have been widely studied with pH neutralization as its commo...

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Main Authors: Casey Oliver A. Turingan, Giulio B. Singson, Bernadette T. Melchor, Richard D. Alorro, Arnel B. Beltran, Aileen H. Orbecido
Format: Article
Language:English
Published: MDPI AG 2020-09-01
Series:Minerals
Subjects:
iron hydroxide
iron oxyhydroxide
acid mine drainage
nickel ore
fly ash
concrete aggregate
Online Access:https://www.mdpi.com/2075-163X/10/10/845
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spelling doaj-b9746458c1be427abaef98ee340789e72020-11-25T01:59:39ZengMDPI AGMinerals2075-163X2020-09-011084584510.3390/min10100845Evaluation of Efficiencies of Locally Available Neutralizing Agents for Passive Treatment of Acid Mine DrainageCasey Oliver A. Turingan0Giulio B. Singson1Bernadette T. Melchor2Richard D. Alorro3Arnel B. Beltran4Aileen H. Orbecido5Chemical Engineering Department, De La Salle University, Manila 1004, PhilippinesChemical Engineering Department, De La Salle University, Manila 1004, PhilippinesChemical Engineering Department, De La Salle University, Manila 1004, PhilippinesWestern Australia School of Mines: Minerals, Energy and Chemical Engineering, Curtin University, Kalgoorlie Campus, Kalgoorlie, WA 6430, AustraliaChemical Engineering Department, De La Salle University, Manila 1004, PhilippinesChemical Engineering Department, De La Salle University, Manila 1004, PhilippinesAcid mine drainage (AMD) generated from the mining industry elevates environmental concerns due to the pollution and contamination it causes to bodies of water. Over the years, passive treatment of AMD using alkalinity-generating materials have been widely studied with pH neutralization as its commonly observed mechanism. During the treatment process, heavy metal removal is also promoted by precipitation due to pH change or through adsorption facilitated by the mineral component of the materials. In this study, four materials were used and investigated: (1) a low grade ore (LGO) made up of goethite, calcium oxide, and manganese aluminum oxide (2–3) limestone and concrete aggregates (CA) composed of calcite, and (4) fly ash consisting of quartz, hematite, and magnetite. The performance of each alkalinity-generating agent at varying AMD/media ratios was based on the change in pH, total dissolved solids (TDS), oxidation reduction potential (E<sub>H</sub>); and heavy metals (Fe, Ni, and Al) removal and sulfate concentration reduction. Concrete aggregate displayed the most significant effect in treating AMD after raising the pH to 12.42 and removing 99% Fe, 99% Ni, 96% Al, and 57% sulfates. Afterwards, the efficiency of CA at various particle sizes were evaluated over 1 h. The smallest range at 2.00–3.35mm was observed to be most effective after 60 min, raising the pH to 6.78 and reducing 94% Fe, 78% Ni, and 92% Al, but only 28% sulfates. Larger particles of CA were able to remove higher amounts of sulfate up to 57%, similar to the jar test. Overall, CA is an effective treatment media for neutralization; however, its performance can be complemented by a second media for heavy metal and sulfate removal.https://www.mdpi.com/2075-163X/10/10/845iron hydroxideiron oxyhydroxideacid mine drainagenickel orefly ashconcrete aggregate
collection DOAJ
language English
format Article
sources DOAJ
author Casey Oliver A. Turingan
Giulio B. Singson
Bernadette T. Melchor
Richard D. Alorro
Arnel B. Beltran
Aileen H. Orbecido
spellingShingle Casey Oliver A. Turingan
Giulio B. Singson
Bernadette T. Melchor
Richard D. Alorro
Arnel B. Beltran
Aileen H. Orbecido
Evaluation of Efficiencies of Locally Available Neutralizing Agents for Passive Treatment of Acid Mine Drainage
Minerals
iron hydroxide
iron oxyhydroxide
acid mine drainage
nickel ore
fly ash
concrete aggregate
author_facet Casey Oliver A. Turingan
Giulio B. Singson
Bernadette T. Melchor
Richard D. Alorro
Arnel B. Beltran
Aileen H. Orbecido
author_sort Casey Oliver A. Turingan
title Evaluation of Efficiencies of Locally Available Neutralizing Agents for Passive Treatment of Acid Mine Drainage
title_short Evaluation of Efficiencies of Locally Available Neutralizing Agents for Passive Treatment of Acid Mine Drainage
title_full Evaluation of Efficiencies of Locally Available Neutralizing Agents for Passive Treatment of Acid Mine Drainage
title_fullStr Evaluation of Efficiencies of Locally Available Neutralizing Agents for Passive Treatment of Acid Mine Drainage
title_full_unstemmed Evaluation of Efficiencies of Locally Available Neutralizing Agents for Passive Treatment of Acid Mine Drainage
title_sort evaluation of efficiencies of locally available neutralizing agents for passive treatment of acid mine drainage
publisher MDPI AG
series Minerals
issn 2075-163X
publishDate 2020-09-01
description Acid mine drainage (AMD) generated from the mining industry elevates environmental concerns due to the pollution and contamination it causes to bodies of water. Over the years, passive treatment of AMD using alkalinity-generating materials have been widely studied with pH neutralization as its commonly observed mechanism. During the treatment process, heavy metal removal is also promoted by precipitation due to pH change or through adsorption facilitated by the mineral component of the materials. In this study, four materials were used and investigated: (1) a low grade ore (LGO) made up of goethite, calcium oxide, and manganese aluminum oxide (2–3) limestone and concrete aggregates (CA) composed of calcite, and (4) fly ash consisting of quartz, hematite, and magnetite. The performance of each alkalinity-generating agent at varying AMD/media ratios was based on the change in pH, total dissolved solids (TDS), oxidation reduction potential (E<sub>H</sub>); and heavy metals (Fe, Ni, and Al) removal and sulfate concentration reduction. Concrete aggregate displayed the most significant effect in treating AMD after raising the pH to 12.42 and removing 99% Fe, 99% Ni, 96% Al, and 57% sulfates. Afterwards, the efficiency of CA at various particle sizes were evaluated over 1 h. The smallest range at 2.00–3.35mm was observed to be most effective after 60 min, raising the pH to 6.78 and reducing 94% Fe, 78% Ni, and 92% Al, but only 28% sulfates. Larger particles of CA were able to remove higher amounts of sulfate up to 57%, similar to the jar test. Overall, CA is an effective treatment media for neutralization; however, its performance can be complemented by a second media for heavy metal and sulfate removal.
topic iron hydroxide
iron oxyhydroxide
acid mine drainage
nickel ore
fly ash
concrete aggregate
url https://www.mdpi.com/2075-163X/10/10/845
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