Selective leaching of copper and zinc from primary ores and secondary mineral residues using biogenic ammonia

Adam J. Williamson; Florian Verbruggen; Vania S. Chavez Rico; Jef Bergmans; Jeroen Spooren; Lourdes Yurramendi; Gijs Du Laing; Nico Boon; Tom Hennebel

doi:10.1016/j.jhazmat.2020.123842

Selective leaching of copper and zinc from primary ores and secondary mineral residues using biogenic ammonia

Adam J. Williamson
, Florian Verbruggen
, Vania S. Chavez Rico
, Jef Bergmans
, Jeroen Spooren
, Lourdes Yurramendi
, Gijs Du Laing
, Nico Boon
, Tom Hennebel

Valorización de residuos

Ghent University
SIM vzw
Flemish Institute for Technological Research

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

42 Citas (Scopus)

5 Descargas (Pure)

Resumen

With the number of easily accessible ores depleting, alternate primary and secondary sources are required to meet the increasing demand of economically important metals. Whilst highly abundant, these materials are of lower grade with respect to traditional ores, thus highly selective and sustainable metal extraction technologies are needed to reduce processing costs. Here, we investigated the metal leaching potential of biogenic ammonia produced by a ureolytic strain of Lysinibacillus sphaericus on eight primary and secondary materials, comprised of mining and metallurgical residues, sludges and automotive shredder residues (ASR). For the majority of materials, moderate to high yields (30–70%) and very high selectivity (>97% against iron) of copper and zinc were obtained with 1 mol L−1 total ammonia. Optimal leaching was achieved and further refined for the ASR in a two-step indirect leaching system with biogenic ammonia. Copper leaching was the result of local corrosion and differences in leaching against the synthetic (NH4)2CO3 control could be accounted for by pH shifts from microbial metabolism, subsequently altering free NH3 required for coordination. These results provide important findings for future sustainable metal recovery technologies from secondary materials.

Idioma original	Inglés
Número de artículo	123842
Páginas (desde-hasta)	123842
Número de páginas	1
Publicación	Journal of Hazardous Materials
Volumen	403
DOI	https://doi.org/10.1016/j.jhazmat.2020.123842
Estado	Publicada - 5 feb 2021

ODS de las Naciones Unidas

Este resultado contribuye a los siguientes Objetivos de Desarrollo Sostenible

ODS 12: Producción y consumo responsables

Palabras clave

Biohydrometallurgy
Ureolysis
Metal recovery
Tailings
Waste processing

Project and Funding Information

Project ID
info:eu-repo/grantAgreement/EC/H2020/690088/EU/Metal Recovery from Low Grade Ores and Wastes Plus/METGROW PLUS
Funding Info
This work was conducted under the financial support of the Strategic Initiative Materials in Flanders (SIM) (SBO-SMART: Sustainable Metal Extraction from Tailings, grant no. HBC.2016.0456) and the European Union’s Horizon 2020 research and innovation programme, Metal Re-covery from Low-Grade Ores and Wastes Plus (METGROW+, grant no. 690088) . FV acknowledges support by the Flemish Agency for Inno-vation and Entrepreneurship (Vlaio) via a Baekeland PhD fellowship (HBC.2017.0224) and by the Research & Development Umicore Group. We would like to thank Pieter Ostermeyer and Karel Folens for assis-tance with thermodynamic modelling and CMET and ECOCHEM group members and SMART/METGROW+partners for valuable discussions throughout the projec.

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abstract = "With the number of easily accessible ores depleting, alternate primary and secondary sources are required to meet the increasing demand of economically important metals. Whilst highly abundant, these materials are of lower grade with respect to traditional ores, thus highly selective and sustainable metal extraction technologies are needed to reduce processing costs. Here, we investigated the metal leaching potential of biogenic ammonia produced by a ureolytic strain of Lysinibacillus sphaericus on eight primary and secondary materials, comprised of mining and metallurgical residues, sludges and automotive shredder residues (ASR). For the majority of materials, moderate to high yields (30–70\%) and very high selectivity (>97\% against iron) of copper and zinc were obtained with 1 mol L−1 total ammonia. Optimal leaching was achieved and further refined for the ASR in a two-step indirect leaching system with biogenic ammonia. Copper leaching was the result of local corrosion and differences in leaching against the synthetic (NH4)2CO3 control could be accounted for by pH shifts from microbial metabolism, subsequently altering free NH3 required for coordination. These results provide important findings for future sustainable metal recovery technologies from secondary materials.",

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AU - Verbruggen, Florian

AU - Chavez Rico, Vania S.

AU - Bergmans, Jef

AU - Spooren, Jeroen

AU - Yurramendi, Lourdes

AU - Laing, Gijs Du

AU - Boon, Nico

AU - Hennebel, Tom

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AB - With the number of easily accessible ores depleting, alternate primary and secondary sources are required to meet the increasing demand of economically important metals. Whilst highly abundant, these materials are of lower grade with respect to traditional ores, thus highly selective and sustainable metal extraction technologies are needed to reduce processing costs. Here, we investigated the metal leaching potential of biogenic ammonia produced by a ureolytic strain of Lysinibacillus sphaericus on eight primary and secondary materials, comprised of mining and metallurgical residues, sludges and automotive shredder residues (ASR). For the majority of materials, moderate to high yields (30–70%) and very high selectivity (>97% against iron) of copper and zinc were obtained with 1 mol L−1 total ammonia. Optimal leaching was achieved and further refined for the ASR in a two-step indirect leaching system with biogenic ammonia. Copper leaching was the result of local corrosion and differences in leaching against the synthetic (NH4)2CO3 control could be accounted for by pH shifts from microbial metabolism, subsequently altering free NH3 required for coordination. These results provide important findings for future sustainable metal recovery technologies from secondary materials.

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KW - Waste processing

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KW - Metal recovery

KW - Tailings

KW - Waste processing

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Selective leaching of copper and zinc from primary ores and secondary mineral residues using biogenic ammonia

Resumen

ODS de las Naciones Unidas

Palabras clave

Project and Funding Information

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