Pathway to Prediction of Pyrite Floatability from Copper Ore Geological Domain Data

The depletion of mining resources forces the mining industry to process more heterogeneous and complex orebodies. The inherent heterogeneity of these orebodies and their relation to processing recoveries have received considerable interest in recent years. The properties of ores, such as mineral com...
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Autor*in:	Unzile Yenial-Arslan [verfasserIn] Mayra Jefferson [verfasserIn] Catherine Curtis-Morar [verfasserIn] Elizaveta Forbes [verfasserIn]

Format:	E-Artikel
Sprache:	Englisch

Erschienen:	2023

Schlagwörter:	ore domain heterogeneity geology pyrite flotation

Übergeordnetes Werk:	In: Minerals - MDPI AG, 2012, 13(2023), 6, p 801
Übergeordnetes Werk:	volume:13 ; year:2023 ; number:6, p 801

Links:	Link aufrufen Link aufrufen Link aufrufen Journal toc

DOI / URN:	10.3390/min13060801

Katalog-ID:	DOAJ094093989

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language	English
source	In Minerals 13(2023), 6, p 801 volume:13 year:2023 number:6, p 801
sourceStr	In Minerals 13(2023), 6, p 801 volume:13 year:2023 number:6, p 801
format_phy_str_mv	Article
institution	findex.gbv.de
topic_facet	ore domain heterogeneity geology pyrite flotation Mineralogy
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container_title	Minerals
authorswithroles_txt_mv	Unzile Yenial-Arslan @@aut@@ Mayra Jefferson @@aut@@ Catherine Curtis-Morar @@aut@@ Elizaveta Forbes @@aut@@
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callnumber-first	Q - Science
author	Unzile Yenial-Arslan
spellingShingle	Unzile Yenial-Arslan misc QE351-399.2 misc ore domain misc heterogeneity misc geology misc pyrite misc flotation misc Mineralogy Pathway to Prediction of Pyrite Floatability from Copper Ore Geological Domain Data
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topic_title	QE351-399.2 Pathway to Prediction of Pyrite Floatability from Copper Ore Geological Domain Data ore domain heterogeneity geology pyrite flotation
topic	misc QE351-399.2 misc ore domain misc heterogeneity misc geology misc pyrite misc flotation misc Mineralogy
topic_unstemmed	misc QE351-399.2 misc ore domain misc heterogeneity misc geology misc pyrite misc flotation misc Mineralogy
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title	Pathway to Prediction of Pyrite Floatability from Copper Ore Geological Domain Data
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title_sort	pathway to prediction of pyrite floatability from copper ore geological domain data
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title_auth	Pathway to Prediction of Pyrite Floatability from Copper Ore Geological Domain Data
abstract	The depletion of mining resources forces the mining industry to process more heterogeneous and complex orebodies. The inherent heterogeneity of these orebodies and their relation to processing recoveries have received considerable interest in recent years. The properties of ores, such as mineral composition and association, are known to affect flotation performance. Even ores with similar compositions can vary significantly regarding their texture, where the same minerals can occur in different forms. Therefore, very careful geometallurgical planning is needed to overcome the recovery losses. Glencore’s Mount Isa Copper Operation has reported historical difficulties decreasing the copper losses associated with natural floatable pyrites. Understanding the rock properties of naturally floatable pyrites and how they relate to chalcopyrite losses is crucial for concentrator operations. The Mount Isa geometallurgy team is looking for proxies for predicting copper losses and natural floatable pyrites to improve mine planning. This paper presents an approach for predicting the collector-less flotation of pyrite, as well as chalcopyrite losses from rock properties. The statistical analysis between the rock quality and ore type gives an indication of the chalcopyrite losses and natural floatable pyrites, which has potential use in geometallurgy plans.
abstractGer	The depletion of mining resources forces the mining industry to process more heterogeneous and complex orebodies. The inherent heterogeneity of these orebodies and their relation to processing recoveries have received considerable interest in recent years. The properties of ores, such as mineral composition and association, are known to affect flotation performance. Even ores with similar compositions can vary significantly regarding their texture, where the same minerals can occur in different forms. Therefore, very careful geometallurgical planning is needed to overcome the recovery losses. Glencore’s Mount Isa Copper Operation has reported historical difficulties decreasing the copper losses associated with natural floatable pyrites. Understanding the rock properties of naturally floatable pyrites and how they relate to chalcopyrite losses is crucial for concentrator operations. The Mount Isa geometallurgy team is looking for proxies for predicting copper losses and natural floatable pyrites to improve mine planning. This paper presents an approach for predicting the collector-less flotation of pyrite, as well as chalcopyrite losses from rock properties. The statistical analysis between the rock quality and ore type gives an indication of the chalcopyrite losses and natural floatable pyrites, which has potential use in geometallurgy plans.
abstract_unstemmed	The depletion of mining resources forces the mining industry to process more heterogeneous and complex orebodies. The inherent heterogeneity of these orebodies and their relation to processing recoveries have received considerable interest in recent years. The properties of ores, such as mineral composition and association, are known to affect flotation performance. Even ores with similar compositions can vary significantly regarding their texture, where the same minerals can occur in different forms. Therefore, very careful geometallurgical planning is needed to overcome the recovery losses. Glencore’s Mount Isa Copper Operation has reported historical difficulties decreasing the copper losses associated with natural floatable pyrites. Understanding the rock properties of naturally floatable pyrites and how they relate to chalcopyrite losses is crucial for concentrator operations. The Mount Isa geometallurgy team is looking for proxies for predicting copper losses and natural floatable pyrites to improve mine planning. This paper presents an approach for predicting the collector-less flotation of pyrite, as well as chalcopyrite losses from rock properties. The statistical analysis between the rock quality and ore type gives an indication of the chalcopyrite losses and natural floatable pyrites, which has potential use in geometallurgy plans.
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title_short	Pathway to Prediction of Pyrite Floatability from Copper Ore Geological Domain Data
url	https://doi.org/10.3390/min13060801 https://doaj.org/article/7e9f1c0bb97f48de9142f76676a62f51 https://www.mdpi.com/2075-163X/13/6/801 https://doaj.org/toc/2075-163X
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