Mercury deposits of western California: an overview

Studemeister, Paul A.

doi:10.1007/bf00199786

Cited by 15 publications

(4 citation statements)

References 24 publications

(36 reference statements)

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“…Most notably, mindat.org records more than 300 separate mercury mines, prospects, dumps, placers, and other localized Hg mineral sites associated with the Pliocene to Recent (5.3 to 0 Ma) hydrothermal systems of west-central California. This important mining district, including the New Almadén mine in Santa Clara County and the New Idria mine in San Benito County (two of the world's largest mercury producers), represents a single mineralized province with ages restricted to the last 5.3 million years (Bailey 1962;White 1981;Studemeister 1984;Varekamp and Buseck 1984;Barnes 1997;Smith et al 2008). Similarly, hundreds of separate localities in southwest Alaska (Szumigala 1996), central Arizona (Eastoe et al 1990), west Texas (Thompson 1954Henry et al 1997), and southwest Utah (Cunningham et al 1982), as well as clusters of localities in many countries, represent individual mineralized districts.…”

Section: Mercury Mineral Age and Locality Datamentioning

confidence: 99%

Mercury (Hg) mineral evolution: A mineralogical record of supercontinent assembly, changing ocean geochemistry, and the emerging terrestrial biosphere

Hazen

Golden

Downs

et al. 2012

American Mineralogist

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Analyses of the temporal and geographic distribution of earliest recorded appearances of the 88 IMA-approved mercury minerals plus two potentially valid species exemplify principles of mineral evolution. Metacinnabar (HgS) and native Hg are the only two species reported from meteorites, specifically, the primitive H3 Tieschitz chondrite with an age of 4550 Ma. Since the first terrestrial appearance of cinnabar more than 3 billion years ago, mercury minerals have been present continuously at or near Earth's surface.Mercury mineral evolution is characterized by episodic deposition and diversification, perhaps associated with the supercontinent cycle. We observe statistically significant increases in the number of reported Hg mineral localities and new Hg species at ~2.8-2.6, ~1.9-1.8, and ~0.43-0.25 Gaintervals that correlate with episodes of presumed supercontinent assembly and associated orogenies of Kenorland (Superia), Columbia (Nuna), and Pangea, respectively. In constrast, few Hg deposits or new species of mercury minerals are reported from the intervals of supercontinent stability and breakup at ~2.5-1.9, ~1.8-1.2, and 1.1-0.8 Ga. The interval of Pangean supercontinent stability and breakup (~250-65 Ma) is also marked by a significant decline in reported mercury mineralization; however, rocks of the last 65 million years, during which Pangea has continued to diverge, is characterized by numerous ephemeral near-surface Hg deposits.The period ~1.2-1.0 Ga, during the assembly of the Rodinian supercontinent, is an exception because of the absence of new Hg minerals or deposits from this period. Episodes of Hg mineralization reflect metamorphism of Hg-enriched marine black shales at zones of continental convergence. We suggest that Hg was effectively sequestered as insoluble nanoparticles of cinnabar (HgS) or tiemannite (HgSe) during the period of the sulfidic "intermediate ocean" (~1.85-0.85 Ga); consequently, few Hg deposits formed during the aggregation of Rodinia, whereas several deposits date from 800-600 Ma, a period that overlaps with the rifting and breakup of Rodinia.Nearly all Hg mineral species (87 of 90 known), as well as all major economic Hg deposits, are known to occur in formations ≤400 million years old. This relatively recent diversification arises, in part, from the ephemeral nature of many Hg minerals. In addition, mercury mineralization is strongly enhanced by interactions with organic matter, so the relatively recent pulse of new Hg minerals may reflect the rise of a terrestrial biosphere at ~400 Ma.

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Section: Mercury Mineral Age and Locality Datamentioning

confidence: 99%

Mercury (Hg) mineral evolution: A mineralogical record of supercontinent assembly, changing ocean geochemistry, and the emerging terrestrial biosphere

Hazen

Golden

Downs

et al. 2012

American Mineralogist

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“…Representative examples include the Wanshan Hg, Huayuan Pb-Zn, and Dazhuyuan Ba-F deposits (Figure 1; Wang et al, 2010;Hu et al, 2017;Zou et al, 2022). These deposits are poorly dated because of the simple mineral paragenesis comprising sulphides associated with calcite/dolomite, barite, fluorite, and rare quartz, and because of the low contents of radiogenic elements (Studemeister, 1984;Luo et al, 2020). Reported ages include a Rb-Sr age of 431±24 Ma for sphalerite from the Aozigang Pb-Zn deposit (Cao et al, 2015), Sm-Nd age of 364±24 Ma for calcite from the Luanyantang Hg deposit (Wang and Wen, 2015), and Rb-Sr age of 492±37 Ma for fluid inclusions hosted in quartz from the Pingqiu Au deposit (Hu et al, 2007).…”

Section: Introductionmentioning

confidence: 99%

A Paleozoic mercury mineralisation event in South China: In situ U-Pb dating and chemical compositions of calcite from the Jianyan Hg deposit

Luo

Zhou

Cugerone

et al. 2023

Sci. China Earth Sci.

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HAL is a multi-disciplinary open access archive for the deposit and dissemination of scientific research documents, whether they are published or not. The documents may come from teaching and research institutions in France or abroad, or from public or private research centers. L'archive ouverte pluridisciplinaire HAL, est destinée au dépôt et à la diffusion de documents scientifiques de niveau recherche, publiés ou non, émanant des établissements d'enseignement et de recherche français ou étrangers, des laboratoires publics ou privés.

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“…Akçay et al 2006;Martín-Izard et al 2009) and ii) epithermal deposits like the silica-carbonate deposits formed during hydrothermal alteration and replacement of serpentinite bodies (< 5.3 Ma in age; New Almadén and New Idria in California, USA; e.g. Studemeister 1984;Smith et al 2008), as well as numerous hot-spring mercury deposits worldwide (e.g. White 1981; Hampton et al 2004).…”

Section: Introductionmentioning

confidence: 99%

Fluid inclusion study of the Horní Luby cinnabar deposit, Saxothuringian Zone, Bohemian Massif: clues for the metamorphic remobilization of mercury

Velebil¹,

Zachariáš²

2013

J. Geosci.

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The stratiform deposit of mercury at Horní Luby near Cheb (Czech Republic) is hosted by Ordovician phyllites of Vogtland-Saxony Paleozoic Unit in the Saxothuringian Zone of the Bohemian Massif. Ore is represented by cinnabar disseminated within the phyllite and by lenticular bodies rich in massive cinnabar (lenses with a thickness of up to 1 m and length along the strike varying from less than 1 m up to 20 m). Cinnabar is accompanied by pyrite and locally also siderite. The P-T history of the mineralization was deciphered by the study of fluid inclusions. Early fluids are represented by a homogenous H 2 O-CO 2 fluid trapped in secretion quartz. This fluid underwent several heterogenization events starting from approximately 300 °C and continued down to 200-150 °C. Metamorphic quartz of secretion origin crystallized at ~300 °C, while hydrothermal pyrite crystallized at 220-210 °C and cinnabar at 195-160 °C. The formation of the richest ore was associated with the replacement of metamorphic quartz in phyllites by the cinnabar in weakly alkaline solutions. The cinnabar is pure phase, free of admixtures (Bi, Sb, Zn, Fe, and Cu). It is accompanied by minute blebs of Hg-bearing sphalerite (11-12 wt. % Hg) that might indicate earlier presence of the zincian metacinnabar and more complex metamorphic history of the ore. The primary source of mercury is thought to be Lower Paleozoic submarine volcanism. The formation of ore bodies is, however, associated with metamorphic mobilization of mercury during the late stages of the Variscan orogeny. Despite being relatively small, the mercury deposit at Horní Luby competed with the mines in Idrija (Slovenia) and Almadén (Spain) in the 16 th century. The production of mercury at Horní Luby is estimated to have corresponded to c. 10-30 % of the mercury production in the mines of Idrija and Almadén at that time. In addition to Venice, the mercury from Horní Luby was also supplied to Nürnberg, Antwerp and Lyon. In 1520-1540, the production of mercury from the Horní Luby mines was 6 to 15 tons per annum. The mines were abandoned in 1597. Attempts to reinstitute mining activity in the 17 th , 18 th and 19 th centuries were not very extensive and always failed. The total production of the Horní Luby mines during the whole mining history is estimated to have been at least 200 tons of mercury. Much of this amount was extracted between 1520 and 1540, with a minor portion between 1560-1570.

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Mercury deposits of western California: an overview

Cited by 15 publications

References 24 publications

Mercury (Hg) mineral evolution: A mineralogical record of supercontinent assembly, changing ocean geochemistry, and the emerging terrestrial biosphere

Mercury (Hg) mineral evolution: A mineralogical record of supercontinent assembly, changing ocean geochemistry, and the emerging terrestrial biosphere

A Paleozoic mercury mineralisation event in South China: In situ U-Pb dating and chemical compositions of calcite from the Jianyan Hg deposit

Fluid inclusion study of the Horní Luby cinnabar deposit, Saxothuringian Zone, Bohemian Massif: clues for the metamorphic remobilization of mercury

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