Study of Microbial Cultures for the Bioleaching of Scandium from Alumina Industry By-Products

Study of Microbial Cultures for the Bioleaching of Scandium from Alumina Industry By-Products

The disposal of voluminous, highly alkaline, bauxite residue (BR), the industrial by-product of alumina production by the Bayer process, constitutes an intricate global environmental problem. BR, containing valuable metals such as rare-earth elements (REEs)—in particular, scandium (Sc)—can be used a...

Full description

Bibliographic Details
Main Authors: Kyriaki Kiskira, Theopisti Lymperopoulou, Lamprini-Areti Tsakanika, Charalampos Pavlopoulos, Konstantina Papadopoulou, Klaus-Michael Ochsenkühn, Gerasimos Lyberatos, Maria Ochsenkühn-Petropoulou
Format: Article
Language:English
Published: MDPI AG 2021-06-01
Series:Metals
Subjects:
bauxite residue
scandium
bioleaching
acetobacter
industrial by-product
rare earth elements
Online Access:https://www.mdpi.com/2075-4701/11/6/951
id doaj-caf1825fa0424d399fe2f08dfeb3e7c2
record_format Article
spelling doaj-caf1825fa0424d399fe2f08dfeb3e7c22021-06-30T23:57:19ZengMDPI AGMetals2075-47012021-06-011195195110.3390/met11060951Study of Microbial Cultures for the Bioleaching of Scandium from Alumina Industry By-ProductsKyriaki Kiskira0Theopisti Lymperopoulou1Lamprini-Areti Tsakanika2Charalampos Pavlopoulos3Konstantina Papadopoulou4Klaus-Michael Ochsenkühn5Gerasimos Lyberatos6Maria Ochsenkühn-Petropoulou7Laboratory of Inorganic and Analytical Chemistry, School of Chemical Engineering, Zografou Campus, National Technical University of Athens, Iroon Polytechniou 9, 15773 Athens, GreeceProducts and Operations Quality Control Laboratory School of Chemical Engineering, School of Chemical Engineering, Zografou Campus, National Technical University of Athens, Iroon Polytechniou 9, 15773 Athens, GreeceLaboratory of Inorganic and Analytical Chemistry, School of Chemical Engineering, Zografou Campus, National Technical University of Athens, Iroon Polytechniou 9, 15773 Athens, GreeceLaboratory of Organic Chemical Technology, School of Chemical Engineering, Zografou Campus, National Technical University of Athens, Iroon Polytechniou 9, 15773 Athens, GreeceLaboratory of Organic Chemical Technology, School of Chemical Engineering, Zografou Campus, National Technical University of Athens, Iroon Polytechniou 9, 15773 Athens, GreeceLaboratory of Inorganic and Analytical Chemistry, School of Chemical Engineering, Zografou Campus, National Technical University of Athens, Iroon Polytechniou 9, 15773 Athens, GreeceLaboratory of Organic Chemical Technology, School of Chemical Engineering, Zografou Campus, National Technical University of Athens, Iroon Polytechniou 9, 15773 Athens, GreeceLaboratory of Inorganic and Analytical Chemistry, School of Chemical Engineering, Zografou Campus, National Technical University of Athens, Iroon Polytechniou 9, 15773 Athens, GreeceThe disposal of voluminous, highly alkaline, bauxite residue (BR), the industrial by-product of alumina production by the Bayer process, constitutes an intricate global environmental problem. BR, containing valuable metals such as rare-earth elements (REEs)—in particular, scandium (Sc)—can be used as a secondary source for REE extraction. The scope of this study was the investigation of bioleaching as an innovative and environmentally friendly approach for the extraction of Sc from BR. The bioleaching parameters were studied on Greek BR and experiments were performed using different microbial cultures and solid to liquid ratios (S/L). The maximum extraction of Sc was 42% using <i>Acetobacter tropicalis</i> in a one-step bioleaching process at 1% S/L. The main organic acids produced were acetic, oxalic, and citric. The bioleaching data indicated a probable synergistic effect of the different organic acids produced by microorganisms along with a more targeted leaching mechanism.https://www.mdpi.com/2075-4701/11/6/951bauxite residuescandiumbioleachingacetobacterindustrial by-productrare earth elements
collection DOAJ
language English
format Article
sources DOAJ
author Kyriaki Kiskira
Theopisti Lymperopoulou
Lamprini-Areti Tsakanika
Charalampos Pavlopoulos
Konstantina Papadopoulou
Klaus-Michael Ochsenkühn
Gerasimos Lyberatos
Maria Ochsenkühn-Petropoulou
spellingShingle Kyriaki Kiskira
Theopisti Lymperopoulou
Lamprini-Areti Tsakanika
Charalampos Pavlopoulos
Konstantina Papadopoulou
Klaus-Michael Ochsenkühn
Gerasimos Lyberatos
Maria Ochsenkühn-Petropoulou
Study of Microbial Cultures for the Bioleaching of Scandium from Alumina Industry By-Products
Metals
bauxite residue
scandium
bioleaching
acetobacter
industrial by-product
rare earth elements
author_facet Kyriaki Kiskira
Theopisti Lymperopoulou
Lamprini-Areti Tsakanika
Charalampos Pavlopoulos
Konstantina Papadopoulou
Klaus-Michael Ochsenkühn
Gerasimos Lyberatos
Maria Ochsenkühn-Petropoulou
author_sort Kyriaki Kiskira
title Study of Microbial Cultures for the Bioleaching of Scandium from Alumina Industry By-Products
title_short Study of Microbial Cultures for the Bioleaching of Scandium from Alumina Industry By-Products
title_full Study of Microbial Cultures for the Bioleaching of Scandium from Alumina Industry By-Products
title_fullStr Study of Microbial Cultures for the Bioleaching of Scandium from Alumina Industry By-Products
title_full_unstemmed Study of Microbial Cultures for the Bioleaching of Scandium from Alumina Industry By-Products
title_sort study of microbial cultures for the bioleaching of scandium from alumina industry by-products
publisher MDPI AG
series Metals
issn 2075-4701
publishDate 2021-06-01
description The disposal of voluminous, highly alkaline, bauxite residue (BR), the industrial by-product of alumina production by the Bayer process, constitutes an intricate global environmental problem. BR, containing valuable metals such as rare-earth elements (REEs)—in particular, scandium (Sc)—can be used as a secondary source for REE extraction. The scope of this study was the investigation of bioleaching as an innovative and environmentally friendly approach for the extraction of Sc from BR. The bioleaching parameters were studied on Greek BR and experiments were performed using different microbial cultures and solid to liquid ratios (S/L). The maximum extraction of Sc was 42% using <i>Acetobacter tropicalis</i> in a one-step bioleaching process at 1% S/L. The main organic acids produced were acetic, oxalic, and citric. The bioleaching data indicated a probable synergistic effect of the different organic acids produced by microorganisms along with a more targeted leaching mechanism.
topic bauxite residue
scandium
bioleaching
acetobacter
industrial by-product
rare earth elements
url https://www.mdpi.com/2075-4701/11/6/951
work_keys_str_mv AT kyriakikiskira studyofmicrobialculturesforthebioleachingofscandiumfromaluminaindustrybyproducts
AT theopistilymperopoulou studyofmicrobialculturesforthebioleachingofscandiumfromaluminaindustrybyproducts
AT lampriniaretitsakanika studyofmicrobialculturesforthebioleachingofscandiumfromaluminaindustrybyproducts
AT charalampospavlopoulos studyofmicrobialculturesforthebioleachingofscandiumfromaluminaindustrybyproducts
AT konstantinapapadopoulou studyofmicrobialculturesforthebioleachingofscandiumfromaluminaindustrybyproducts
AT klausmichaelochsenkuhn studyofmicrobialculturesforthebioleachingofscandiumfromaluminaindustrybyproducts
AT gerasimoslyberatos studyofmicrobialculturesforthebioleachingofscandiumfromaluminaindustrybyproducts
AT mariaochsenkuhnpetropoulou studyofmicrobialculturesforthebioleachingofscandiumfromaluminaindustrybyproducts
_version_ 1721350016842334208

Similar Items