TEXTURES AND CHEMICAL COMPOSITIONS OF MAGNETITE FROM IRON OXIDE COPPER-GOLD (IOCG) AND KIRUNA-TYPE IRON OXIDE-APATITE (IOA) DEPOSITS AND THEIR IMPLICATIONS FOR ORE GENESIS AND MAGNETITE CLASSIFICATION SCHEMES
Textural and compositional data of magnetite from Igarape Bahia, Alemao, Sossego, Salobo, and Candelaria iron oxide copper-gold (IOCG) and El Romeral Kiruna-type iron oxide-apatite (IOA) deposits show that some magnetite grains display oscillatory zoning or have been reequilibrated by oxy-exsolution...
| Published in: | Economic Geology |
|---|---|
| Main Authors: | , |
| Format: | Report |
| Language: | English |
| Published: |
SOC ECONOMIC GEOLOGISTS, INC
2019
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| Subjects: | |
| Online Access: | http://ir.gig.ac.cn/handle/344008/41518 https://doi.org/10.5382/econgeo.4651 |
| id |
ftchacadscgigcas:oai:ir.gig.ac.cn:344008/41518 |
|---|---|
| record_format |
openpolar |
| institution |
Open Polar |
| collection |
Guangzhou Institute of Geochemistry: GIG OpenIR (Chinese Academy of Sciences) |
| op_collection_id |
ftchacadscgigcas |
| language |
English |
| topic |
Geochemistry & Geophysics TRACE ELEMENTAL ANALYSES CU-AU DEPOSIT MINERAL REPLACEMENT REACTIONS SILICATE LIQUID IMMISCIBILITY FRANCOIS MOUNTAINS TERRANE FIELD EVIDENCE BEARING EL LACO VOLCANO RE-OS DISSOLUTION-REPRECIPITATION HYDROTHERMAL ALTERATION |
| spellingShingle |
Geochemistry & Geophysics TRACE ELEMENTAL ANALYSES CU-AU DEPOSIT MINERAL REPLACEMENT REACTIONS SILICATE LIQUID IMMISCIBILITY FRANCOIS MOUNTAINS TERRANE FIELD EVIDENCE BEARING EL LACO VOLCANO RE-OS DISSOLUTION-REPRECIPITATION HYDROTHERMAL ALTERATION Huang, Xiao-Wen Beaudoin, Georges TEXTURES AND CHEMICAL COMPOSITIONS OF MAGNETITE FROM IRON OXIDE COPPER-GOLD (IOCG) AND KIRUNA-TYPE IRON OXIDE-APATITE (IOA) DEPOSITS AND THEIR IMPLICATIONS FOR ORE GENESIS AND MAGNETITE CLASSIFICATION SCHEMES |
| topic_facet |
Geochemistry & Geophysics TRACE ELEMENTAL ANALYSES CU-AU DEPOSIT MINERAL REPLACEMENT REACTIONS SILICATE LIQUID IMMISCIBILITY FRANCOIS MOUNTAINS TERRANE FIELD EVIDENCE BEARING EL LACO VOLCANO RE-OS DISSOLUTION-REPRECIPITATION HYDROTHERMAL ALTERATION |
| description |
Textural and compositional data of magnetite from Igarape Bahia, Alemao, Sossego, Salobo, and Candelaria iron oxide copper-gold (IOCG) and El Romeral Kiruna-type iron oxide-apatite (IOA) deposits show that some magnetite grains display oscillatory zoning or have been reequilibrated by oxy-exsolution, coupled dissolution and reprecipitation (CDR) reactions, and/or recrystallization. Textures formed via CDR are most widespread in the studied samples. The original oscillatory zoning was likely derived from the crystal growth during fluctuating fluid compositions rather than from variation in temperature and oxygen fugacity. The oxy-exsolution of ilmenite in magnetite is attributed to increasing oxygen fugacity and decreasing temperature with alteration and mineralization, resulting in product magnetite with lower Ti and higher V contents. Recrystallization of some magnetite grains is commonly due to high-temperature annealing that retained primary compositions. Two different types of CDR processes are defined according to textures and chemical compositions of different generations of magnetite. The first generation of magnetite (Mag-1) is an inclusion-rich and trace element-rich core, which was replaced by an inclusion-poor and trace element-poor rim (Mag-2). The third generation of magnetite (Mag-3), inclusion poor but trace element rich, occurs as veins replacing Mag-2 along fractures or grain margins. Type 1 CDR process transforming Mag-1 to Mag-2 is more extensive and is similar to processes reported in skarn deposits, whereas type 2 CDR process is local, transforming Mag-2 to Mag-3. During type 1 CDR process, minor and trace elements Si, K, Ca, Mg, Al, and Mn in magnetite are excluded, and Fe contents increase to various extents, in contrast to type 2 CDR process, which is characterized by increased contents of Si, K, Ca, Mg, Al, and Mn. Type 1 CDR process is possibly induced by the changing fluid composition and/or decreasing temperature during progressive alteration and ore formation, whereas type 2 CDR process can be interpreted as post-ore replacement due to a new pulse of magmatic-hydrothermal fluids. The identification of magnetite core (Mag-1) with igneous origin and rim (Mag-2) with magmatic-hydrothermal origin in the Sossego IOCG and El Romeral IOA deposits supports a fluid changing from magmatic to magmatic-hydrothermal during IOCG and IOA formation and indicates a genetic link between these two deposit types. The large data set here further demonstrates that magnetite is susceptible to textural and compositional reequilibration during high-temperature magmatic and magmatic-hydrothermal processes. Reequilibrated magnetite, particularly that formed by CDR processes, has a chemical composition that can be different from that of primary magnetite. Modified magnetite, therefore, cannot be used to discriminate its primary origin or to interpret its provenance in overburden sediments. Therefore, in situ chemical analysis of magnetite combined with textural characterization is necessary to understand the origin of magnetite in IOCG and IOA deposits. |
| format |
Report |
| author |
Huang, Xiao-Wen Beaudoin, Georges |
| author_facet |
Huang, Xiao-Wen Beaudoin, Georges |
| author_sort |
Huang, Xiao-Wen |
| title |
TEXTURES AND CHEMICAL COMPOSITIONS OF MAGNETITE FROM IRON OXIDE COPPER-GOLD (IOCG) AND KIRUNA-TYPE IRON OXIDE-APATITE (IOA) DEPOSITS AND THEIR IMPLICATIONS FOR ORE GENESIS AND MAGNETITE CLASSIFICATION SCHEMES |
| title_short |
TEXTURES AND CHEMICAL COMPOSITIONS OF MAGNETITE FROM IRON OXIDE COPPER-GOLD (IOCG) AND KIRUNA-TYPE IRON OXIDE-APATITE (IOA) DEPOSITS AND THEIR IMPLICATIONS FOR ORE GENESIS AND MAGNETITE CLASSIFICATION SCHEMES |
| title_full |
TEXTURES AND CHEMICAL COMPOSITIONS OF MAGNETITE FROM IRON OXIDE COPPER-GOLD (IOCG) AND KIRUNA-TYPE IRON OXIDE-APATITE (IOA) DEPOSITS AND THEIR IMPLICATIONS FOR ORE GENESIS AND MAGNETITE CLASSIFICATION SCHEMES |
| title_fullStr |
TEXTURES AND CHEMICAL COMPOSITIONS OF MAGNETITE FROM IRON OXIDE COPPER-GOLD (IOCG) AND KIRUNA-TYPE IRON OXIDE-APATITE (IOA) DEPOSITS AND THEIR IMPLICATIONS FOR ORE GENESIS AND MAGNETITE CLASSIFICATION SCHEMES |
| title_full_unstemmed |
TEXTURES AND CHEMICAL COMPOSITIONS OF MAGNETITE FROM IRON OXIDE COPPER-GOLD (IOCG) AND KIRUNA-TYPE IRON OXIDE-APATITE (IOA) DEPOSITS AND THEIR IMPLICATIONS FOR ORE GENESIS AND MAGNETITE CLASSIFICATION SCHEMES |
| title_sort |
textures and chemical compositions of magnetite from iron oxide copper-gold (iocg) and kiruna-type iron oxide-apatite (ioa) deposits and their implications for ore genesis and magnetite classification schemes |
| publisher |
SOC ECONOMIC GEOLOGISTS, INC |
| publishDate |
2019 |
| url |
http://ir.gig.ac.cn/handle/344008/41518 https://doi.org/10.5382/econgeo.4651 |
| long_lat |
ENVELOPE(-63.750,-63.750,-66.167,-66.167) |
| geographic |
Candelaria Kiruna |
| geographic_facet |
Candelaria Kiruna |
| genre |
Kiruna |
| genre_facet |
Kiruna |
| op_relation |
ECONOMIC GEOLOGY http://ir.gig.ac.cn/handle/344008/41518 doi:10.5382/econgeo.4651 |
| op_doi |
https://doi.org/10.5382/econgeo.4651 |
| container_title |
Economic Geology |
| container_volume |
114 |
| container_issue |
5 |
| container_start_page |
953 |
| op_container_end_page |
979 |
| _version_ |
1766058334922735616 |
| spelling |
ftchacadscgigcas:oai:ir.gig.ac.cn:344008/41518 2023-05-15T17:04:16+02:00 TEXTURES AND CHEMICAL COMPOSITIONS OF MAGNETITE FROM IRON OXIDE COPPER-GOLD (IOCG) AND KIRUNA-TYPE IRON OXIDE-APATITE (IOA) DEPOSITS AND THEIR IMPLICATIONS FOR ORE GENESIS AND MAGNETITE CLASSIFICATION SCHEMES Huang, Xiao-Wen Beaudoin, Georges 2019-08-01 http://ir.gig.ac.cn/handle/344008/41518 https://doi.org/10.5382/econgeo.4651 英语 eng SOC ECONOMIC GEOLOGISTS, INC ECONOMIC GEOLOGY http://ir.gig.ac.cn/handle/344008/41518 doi:10.5382/econgeo.4651 Geochemistry & Geophysics TRACE ELEMENTAL ANALYSES CU-AU DEPOSIT MINERAL REPLACEMENT REACTIONS SILICATE LIQUID IMMISCIBILITY FRANCOIS MOUNTAINS TERRANE FIELD EVIDENCE BEARING EL LACO VOLCANO RE-OS DISSOLUTION-REPRECIPITATION HYDROTHERMAL ALTERATION 期刊论文 2019 ftchacadscgigcas https://doi.org/10.5382/econgeo.4651 2020-12-22T07:21:39Z Textural and compositional data of magnetite from Igarape Bahia, Alemao, Sossego, Salobo, and Candelaria iron oxide copper-gold (IOCG) and El Romeral Kiruna-type iron oxide-apatite (IOA) deposits show that some magnetite grains display oscillatory zoning or have been reequilibrated by oxy-exsolution, coupled dissolution and reprecipitation (CDR) reactions, and/or recrystallization. Textures formed via CDR are most widespread in the studied samples. The original oscillatory zoning was likely derived from the crystal growth during fluctuating fluid compositions rather than from variation in temperature and oxygen fugacity. The oxy-exsolution of ilmenite in magnetite is attributed to increasing oxygen fugacity and decreasing temperature with alteration and mineralization, resulting in product magnetite with lower Ti and higher V contents. Recrystallization of some magnetite grains is commonly due to high-temperature annealing that retained primary compositions. Two different types of CDR processes are defined according to textures and chemical compositions of different generations of magnetite. The first generation of magnetite (Mag-1) is an inclusion-rich and trace element-rich core, which was replaced by an inclusion-poor and trace element-poor rim (Mag-2). The third generation of magnetite (Mag-3), inclusion poor but trace element rich, occurs as veins replacing Mag-2 along fractures or grain margins. Type 1 CDR process transforming Mag-1 to Mag-2 is more extensive and is similar to processes reported in skarn deposits, whereas type 2 CDR process is local, transforming Mag-2 to Mag-3. During type 1 CDR process, minor and trace elements Si, K, Ca, Mg, Al, and Mn in magnetite are excluded, and Fe contents increase to various extents, in contrast to type 2 CDR process, which is characterized by increased contents of Si, K, Ca, Mg, Al, and Mn. Type 1 CDR process is possibly induced by the changing fluid composition and/or decreasing temperature during progressive alteration and ore formation, whereas type 2 CDR process can be interpreted as post-ore replacement due to a new pulse of magmatic-hydrothermal fluids. The identification of magnetite core (Mag-1) with igneous origin and rim (Mag-2) with magmatic-hydrothermal origin in the Sossego IOCG and El Romeral IOA deposits supports a fluid changing from magmatic to magmatic-hydrothermal during IOCG and IOA formation and indicates a genetic link between these two deposit types. The large data set here further demonstrates that magnetite is susceptible to textural and compositional reequilibration during high-temperature magmatic and magmatic-hydrothermal processes. Reequilibrated magnetite, particularly that formed by CDR processes, has a chemical composition that can be different from that of primary magnetite. Modified magnetite, therefore, cannot be used to discriminate its primary origin or to interpret its provenance in overburden sediments. Therefore, in situ chemical analysis of magnetite combined with textural characterization is necessary to understand the origin of magnetite in IOCG and IOA deposits. Report Kiruna Guangzhou Institute of Geochemistry: GIG OpenIR (Chinese Academy of Sciences) Candelaria ENVELOPE(-63.750,-63.750,-66.167,-66.167) Kiruna Economic Geology 114 5 953 979 |