The Marianas-San Marcos vein system: characteristics of a shallow low sulfidation epithermal Au–Ag deposit in the Cerro Negro district, Deseado Massif, Patagonia, Argentina

Vidal, Conrado Permuy; Guido, Diego M.; Jovic, Sebastián M.; Bodnar, Robert J.; Moncada, Daniel; Melgarejo, Joan Carles; Hames, Willis E.

doi:10.1007/s00126-015-0633-9

Cited by 36 publications

(6 citation statements)

References 62 publications

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“…302 Ma, Yu et al, 2020, this study) and evolved by mixing with meteoric waters at shallow levels during the mineralization process (Figure 20). This finding is consistent with many other global epithermal and subvolcanic hydrothermal deposits (e.g., Simmons, White, & John, 2005;Vidal et al, 2016;Xie et al, 2016), which have shown that meteoric waters are key contributors of the metallic elements in such deposits.…”

Section: Sources Of Ore-forming Materialssupporting

confidence: 92%

Fluid evolution and metallogenesis of the Meiling Cu‐polymetallic deposit in the East Tianshan, NW China: Constraints from ore geology, fluid inclusions, stable isotope, and U–Pb geochronology

Cheng

Yang

Zhang³

et al. 2020

Geological Journal

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The Meiling Cu-polymetallic deposit is located in the Kalatag Cu metallogenic belt of the East Tianshan, Xinjiang, NW China. Multiple-stage hydrothermal activities have resulted in the silicification, chlorite alteration and sericite alteration in this deposit. At least three mineralization stages are recorded: (a) a phase comprising quartz-pyrite veining, (b) a quartz-chalcopyrite-pyrite-sphalerite phase and (c) a quartz-calcite phase, respectively. LA-ICP-MS zircon U-Pb dating yielded 302 ± 2.1 Ma for an orebearing quartz porphyry and 296 ± 3.2 Ma for a post-mineralization diorite porphyry dyke, respectively, indicating that the copper mineralization took place during the Late Carboniferous period (302-296 Ma). Fluid evolution during the three stages of mineralization was determined by a detailed fluid inclusion study: (a) Stage I fluids were trapped under two-phase conditions, as evidenced by the coexistence of vapour-rich (type II) inclusions (T h = 183-242 C, average salinity = 4.8 wt% NaCl equiv.), liquid-rich (type I) inclusions (T h = 171-259 C, average salinity = 5.3 wt% NaCl equiv.), and daughter-bearing (type III) inclusions (T h = 192-208 C, average salinity = 8.6 wt% NaCl equiv.). (b) Stage II fluid inclusions in quartz were also trapped under two-phase conditions (boiling), as identified by the coexistence of V-and Ltype fluid inclusions; L-type inclusions T h between 136 and 218 C (average = 189 C), with salinities of 2.2-7.6 wt% NaCl equiv. (average = 3.8 wt% NaCl equiv.). V-type inclusions homogenized temperatures between 153 and 226 C (average = 192 C), with salinities of 2.4-6.7 wt% NaCl equiv. (average = 3.5 wt% NaCl equiv.). (c) Stage III fluids are represented by inclusions in barren quartz-carbonate veinlets, characterized by homogenization temperatures ranging from 98 to 177 C (average = 135 C) and salinities between 0.5 and 3.2 wt% NaCl equiv. (average = 1.9 wt% NaCl equiv.). The initial hydrothermal fluids are characterized by low-intermediate temperature, low-salinity and near-neutral pH condition, belonging to a H 2 O-NaCl bearing hydrothermal system. The mineralization of the Meiling deposit occurred at a shallow

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Section: Sources Of Ore-forming Materialssupporting

confidence: 92%

Fluid evolution and metallogenesis of the Meiling Cu‐polymetallic deposit in the East Tianshan, NW China: Constraints from ore geology, fluid inclusions, stable isotope, and U–Pb geochronology

Cheng

Yang

Zhang³

et al. 2020

Geological Journal

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“…Numerous occurrences of paleohot springs, represented by sinter and travertine deposits have been recognized in the Deseado Massif (Channing et al, 2007;Echeveste, 2005;Guido and Campbell, 2011, 2014Guido et al, 2002;Marchionni et al, 1999;Schalamuk et al, 1997Schalamuk et al, , 1999a. Their distribution shows that some of these paleohot springs are closely related to economic-grade deposits, such as the case of Cerro Negro (Guido and Campbell, 2012;Permuy Vidal et al, 2013), Mina Martha (Páez, 2012), Manantial Espejo (Wallier, 2009), Cerro Vanguardia (Guido and Campbell, 2014) and La Josefina (this work), among others (Fig. 1).…”

Section: Epithermal Deposits Of the Deseado Massifmentioning

confidence: 57%

La Josefina Au–Ag deposit (Patagonia, Argentina): A Jurassic epithermal deposit formed in a hot spring environment

Moreira

Fernández

2015

Ore Geology Reviews

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“…All these characteristics indicate that the ore-forming materials (C, S, and Pb) were magmatic sources, which were derived directly from magmatic fluids and/or leached from volcanic-subvolcanic rocks by hydrothermal fluids (e.g., Akaryali & Akbulut, 2016;Vidal et al, 2016;Wang, Zeng, Zhou, Chu, & Guo, 2016).…”

Section: Mixing Of Magmatic and Meteoric Waters In Thementioning

confidence: 99%

Hydrothermal evolution and ore genesis of the Jiamante Au deposit in Western Tianshan, Xinjiang, China: Evidence from the geology, fluid inclusions, and C–H–O–S–Pb isotopes

Zheng

Peng

et al. 2021

Geological Journal

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Western Tianshan, Xinjiang. The orebodies occurring mainly as quartz-sulphide veins are hosted in Late Devonian volcanoclastic rocks and granitic porphyries, and structurally controlled by a group of NNW-and NNE-trending extensional faults and volcanic breccias. Primary metallic minerals are chalcopyrite, galena, pyrite, sphalerite, and native gold, with minor amounts of bismuthinite and bismuth. Nonmetallic minerals are dominated by quartz, sericite, chlorite, and calcite. Medium to low temperature hydrothermal alterations are well developed and characterized by silicification, beresitization, phyllic alteration, and chloritization. Two hydrothermal stages were identified: (a) the main-ore quartz-sulphide stage; and (b) the post-ore quartz-calcite stage. Microthermometric measurements indicate that the primary biphase liquid-rich aqueous fluid inclusions within quartz of the main-ore stage homogenize at temperatures (T h ) of 176 to 251 C and have salinities of 2.1 to 7.4 wt% NaCl eqv . A lower range of homogenization temperatures (169 to 212 C) and salinities (1.6 to 5.2 wt% NaCl eqv ) were obtained in calcite of the post-ore stage. The fluid characteristics of moderate to low temperatures and salinities imply that the ore-forming process occurred in an epithermal environment. In addition, there is a positive relationship between T h and salinities consistent with the fluid mixing trend. Together with H-O isotopic data (δD H2O = −118 to −97‰ and δ 18 O H2O = −5.5 to −1.6‰) and fluid characteristics, it is suggested that the ore-forming fluids were a mixture of magmatic and meteoric waters. The δ 13 C values for CO 2 in the hydrothermal fluids range from −3.2 to −2.7‰, and the sulphides have δ 34 S values of −5.2 to 2.9‰ with relatively uniform Pb isotopic

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The Marianas-San Marcos vein system: characteristics of a shallow low sulfidation epithermal Au–Ag deposit in the Cerro Negro district, Deseado Massif, Patagonia, Argentina

Cited by 36 publications

References 62 publications

Fluid evolution and metallogenesis of the Meiling Cu‐polymetallic deposit in the East Tianshan, NW China: Constraints from ore geology, fluid inclusions, stable isotope, and U–Pb geochronology

Fluid evolution and metallogenesis of the Meiling Cu‐polymetallic deposit in the East Tianshan, NW China: Constraints from ore geology, fluid inclusions, stable isotope, and U–Pb geochronology

La Josefina Au–Ag deposit (Patagonia, Argentina): A Jurassic epithermal deposit formed in a hot spring environment

Hydrothermal evolution and ore genesis of the Jiamante Au deposit in Western Tianshan, Xinjiang, China: Evidence from the geology, fluid inclusions, and C–H–O–S–Pb isotopes

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