登录注册
主页关于 MindatMindat手册Mindat的历史版权Who We Are联系我们于 Mindat.org刊登广告
捐赠给 MindatCorporate Sponsorship赞助板页已赞助的板页在 Mindat刊登 广告的广告商于 Mindat.org刊登广告
Learning CenterWhat is a mineral?The most common minerals on earthInformation for EducatorsMindat ArticlesThe Elements书籍及杂志
搜索矿物的性质搜索矿物的化学Advanced Locality Search随意显示任何一 种矿物Random Locality使用minID搜索邻近产地Search Articles搜索词汇表更多搜索选项
搜索:
矿物名称:
地区产地名称:
关键字:
 
Mindat手册添加新照片Rate Photos产区编辑报告Coordinate Completion Report添加词汇表项目
Mining Companies统计会员列表Mineral Museums矿物展及活动The Mindat目录表设备设置
照片搜索Photo Galleries今天最新的照片昨天最新的照片用户照片相集过去每日精选照片相集Mineral Photography

Aguilarite

This page is currently not sponsored. Click here to sponsor this page.
Hide all sections | Show all sections

About AguilariteHide

Formula:
Ag4SeS
Colour:
Bright lead-gray on fresh surfaces
Lustre:
Metallic
Hardness:
Specific Gravity:
7.40 - 7.53
Crystal System:
Monoclinic
Member of:
Name:
Named after Señor P. Aguilar, Superintendent of the San Carlos Mine, Mexico, the type locality.
Isostructural with:
There appear to be two solid solution series in the system: a monoclinic ‘acanthite-like’ series (from Ag2S-Ag2S0.4Se0.6), and an orthorhombic ‘naumannite-like’ series (from Ag2S0.3Se0.7-Ag2Se) (Bindi & Pingitore, 2013; Seryotkin et al., 2015).
The analytical data of Kullerud et al. (2018) cast some doubt about the validity of aguilarite.

The Se analogue of cervelleite.

Compare 'UM1979-11-S:AgAsAuSe', 'UM1979-12-S:AgAsAuSe', and 'UM1979-13-S:AgAsAuSe'.


Classification of AguilariteHide

Approved, 'Grandfathered' (first described prior to 1959)
2.BA.55

2 : SULFIDES and SULFOSALTS (sulfides, selenides, tellurides; arsenides, antimonides, bismuthides; sulfarsenites, sulfantimonites, sulfbismuthites, etc.)
B : Metal Sulfides, M: S > 1: 1 (mainly 2: 1)
A : With Cu, Ag, Au
2.4.1.3

2 : SULFIDES
4 : AmBnXp, with (m+n):p = 2:1
3.2.4

3 : Sulphides, Selenides, Tellurides, Arsenides and Bismuthides (except the arsenides, antimonides and bismuthides of Cu, Ag and Au, which are included in Section 1)
2 : Sulphides etc. of Ag

Physical Properties of AguilariteHide

Metallic
Transparency:
Opaque
Colour:
Bright lead-gray on fresh surfaces
Comment:
dull iron black after exposure to air.
Streak:
grey-black
Hardness:
2½ on Mohs scale
Tenacity:
Sectile
Cleavage:
None Observed
Fracture:
Hackly
Density:
7.40 - 7.53 g/cm3 (Measured)    7.65 g/cm3 (Calculated)

Optical Data of AguilariteHide

Type:
Anisotropic
Anisotropism:
very weak
Reflectivity:
400nmR1=34.8%R2= 35.1%
420nmR1=34.7%R2= 35.2%
440nmR1=34.6%R2= 35.2%
460nmR1=34.7%R2= 35.3%
480nmR1=34.8%R2= 35.3%
500nmR1=34.8%R2= 35.4%
520nmR1=34.6%R2= 35.6%
540nmR1=34.1%R2= 35.5%
560nmR1=33.5%R2= 35.2%
580nmR1=32.8%R2= 34.6%
600nmR1=32.1%R2= 33.8%
620nmR1=31.5%R2= 33.9%
640nmR1=31.0%R2= 32.4%
660nmR1=30.6%R2= 31.8%
680nmR1=30.2%R2= 31.4%
700nmR1=30.0%R2= 31.0%

Reflectance graph
Graph shows reflectance levels at different wavelengths (in nm). Top of box is 100%. Peak reflectance is 35.6%.
R1 shown in black, R2 shown in red

Chemical Properties of AguilariteHide

Formula:
Ag4SeS
Common Impurities:
Cu

Crystallography of AguilariteHide

Crystal System:
Monoclinic
Class (H-M):
2/m - Prismatic
Cell Parameters:
a = 4.33 Å, b = 7.09 Å, c = 7.76 Å
Ratio:
a:b:c = 0.611 : 1 : 1.094
Unit Cell V:
0.00 ų (Calculated from Unit Cell)
Z:
2
Morphology:
In skeletal pseudododecahedral crystals, commonly elongated in the direction of a pseudocubic or pseudo-octahedral edge, to 3 cm; also massive and in intergrowths with acanthite or naumannite.
Comment:
Space group P21/n. Originally assumed to be orthorhombic, with a = 4.33, b = 7.09, c = 7.76 A.

X-Ray Powder DiffractionHide

Powder Diffraction Data:
d-spacingIntensity
2.88 Å(50)
2.67 Å(20)
2.59 Å(20)
2.43 Å(100)
2.23 Å(30)
1.73 Å(30)
1.48 Å(40)
Comments:
Guanajuato, Mexico (ICDD 27-620).

Type Occurrence of AguilariteHide

Other Language Names for AguilariteHide

German:Aguilarit
Italian:Aguilarite
Latvian:Agvilarīts
Simplified Chinese:辉硒银矿
Spanish:Aguilarita

Relationship of Aguilarite to other SpeciesHide

Member of:
Other Members of this group:
AcanthiteAg2SMon. 2/m : P21/m
CervelleiteAg4TeSMon. 2/m

Common AssociatesHide

AcanthiteAg2S
CalciteCaCO3
NaumanniteAg2Se
Pearceite[Ag9CuS4][(Ag,Cu)6(As,Sb)2S7]
ProustiteAg3AsS3
QuartzSiO2
SilverAg
StephaniteAg5SbS4
Associated Minerals Based on Photo Data:
3 photos of Aguilarite associated with Electrum(Au,Ag)
3 photos of Aguilarite associated with NaumanniteAg2Se
2 photos of Aguilarite associated with CalciteCaCO3
2 photos of Aguilarite associated with StephaniteAg5SbS4
2 photos of Aguilarite associated with GoldAu
2 photos of Aguilarite associated with QuartzSiO2
2 photos of Aguilarite associated with Polybasite[(Ag,Cu)6(Sb,As)2S7][Ag9CuS4]

Related Minerals - Nickel-Strunz GroupingHide

2.BA.AlburniteAg8GeTe2S4Iso.
2.BA.DzierżanowskiteCaCu2S2Trig. 3m (3 2/m) : P3m1
2.BA.05ChalcociteCu2SMon. 2/m : P21/b
2.BA.05DjurleiteCu31S16Mon. 2/m
2.BA.05GeeriteCu8S5Trig. 3
2.BA.05RoxbyiteCu9S5Tric. 1 : P1
2.BA.10AniliteCu7S4Orth. mmm (2/m 2/m 2/m) : Pnma
2.BA.10DigeniteCu9S5Trig. 3m (3 2/m) : R3m
2.BA.15BorniteCu5FeS4Orth. mmm (2/m 2/m 2/m) : Pbca
2.BA.20BellidoiteCu2SeTet. 4/m : P42/n
2.BA.20BerzelianiteCu2SeIso. m3m (4/m 3 2/m) : Fm3m
2.BA.25AthabascaiteCu5Se4Orth.
2.BA.25UmangiteCu3Se2Tet.
2.BA.30RickarditeCu7Te5Orth.
2.BA.30WeissiteCu2-xTeHex.
2.BA.35AcanthiteAg2SMon. 2/m : P21/m
2.BA.40MckinstryiteAg5-xCu3+xS4Orth. mmm (2/m 2/m 2/m) : Pnma
2.BA.40StromeyeriteAgCuSOrth. mmm (2/m 2/m 2/m)
2.BA.40dUM2003-13-S:AgAuCuAg6AuCu2S5
2.BA.45JalpaiteAg3CuS2Tet.
2.BA.45SelenojalpaiteAg3CuSe2Tet. 4/mmm (4/m 2/m 2/m) : I41/amd
2.BA.50EucairiteAgCuSeOrth.
2.BA.55NaumanniteAg2SeOrth. 2 2 2 : P21 21 21
2.BA.60CervelleiteAg4TeSMon. 2/m
2.BA.60HessiteAg2TeMon. 2/m : P21/b
2.BA.60ChenguodaiteAg9Fe3+Te2S4Orth.
2.BA.65Henryite(Cu,Ag)3+xTe2 , with x ~ 0.40 Iso. m3m (4/m 3 2/m) : Fd3c
2.BA.65StütziteAg5-xTe3, x = 0.24-0.36Hex. 6 : P6
2.BA.70ArgyroditeAg8GeS6Orth. mm2 : Pna21
2.BA.70CanfielditeAg8SnS6Orth. mm2
2.BA.70Putzite(Cu4.7Ag3.3)GeS6Iso. 4 3m : F4 3m
2.BA.75FischesseriteAg3AuSe2Iso. 4 3 2 : I41 3 2
2.BA.75Penzhinite(Ag,Cu)4Au(S,Se)4Hex.
2.BA.75PetrovskaiteAuAgSMon.
2.BA.75PetziteAg3AuTe2Iso. 4 3 2 : I41 3 2
2.BA.75UytenbogaardtiteAg3AuS2Trig. 3m (3 2/m) : R3c
2.BA.80Bezsmertnovite(Au,Ag)4Cu(Te,Pb)Orth.
2.BA.80BilibinskitePbCu2Au3Te2Iso.
2.BA.80Bogdanovite(Au,Te,Pb)3(Cu,Fe)Iso.

Related Minerals - Dana Grouping (8th Ed.)Hide

2.4.1.1AcanthiteAg2SMon. 2/m : P21/m
2.4.1.2NaumanniteAg2SeOrth. 2 2 2 : P21 21 21

Related Minerals - Hey's Chemical Index of Minerals GroupingHide

3.2.1AcanthiteAg2SMon. 2/m : P21/m
3.2.3NaumanniteAg2SeOrth. 2 2 2 : P21 21 21
3.2.5HessiteAg2TeMon. 2/m : P21/b
3.2.6EmpressiteAgTeOrth. mmm (2/m 2/m 2/m)
3.2.7StütziteAg5-xTe3, x = 0.24-0.36Hex. 6 : P6
3.2.8CervelleiteAg4TeSMon. 2/m
3.2.9DervilliteAg2AsS2Mon. 2/m : P2/b
3.2.10StromeyeriteAgCuSOrth. mmm (2/m 2/m 2/m)
3.2.11MckinstryiteAg5-xCu3+xS4Orth. mmm (2/m 2/m 2/m) : Pnma
3.2.12JalpaiteAg3CuS2Tet.
3.2.13EucairiteAgCuSeOrth.
3.2.14CameroniteCu5-x(Cu,Ag)3+xTe10 (x = 0.43)Mon. 2/m : B2/b
3.2.15Henryite(Cu,Ag)3+xTe2 , with x ~ 0.40 Iso. m3m (4/m 3 2/m) : Fd3c
3.2.16SternbergiteAgFe2S3Orth. mmm (2/m 2/m 2/m)
3.2.17ArgentopyriteAgFe2S3Mon. 2/m
3.2.18Geffroyite(Cu,Fe,Ag)9(Se,S)8Iso. m3m (4/m 3 2/m) : Fm3m
3.2.19ArgentopentlanditeAg(Fe,Ni)8S8Iso. m3m (4/m 3 2/m) : Fm3m

Other InformationHide

Health Risks:
No information on health risks for this material has been entered into the database. You should always treat mineral specimens with care.
Industrial Uses:
Minor silver ore

References for AguilariteHide

Reference List:
Sort by Year (asc) | by Year (desc) | by Author (A-Z) | by Author (Z-A)
Genth, F.A. (1891) Aguilarite, a new species. American Journal of Science: 41: 401-402.
Genth, F.A. (1892) Aguilarite. American Journal of Science: 44: 381-383.
Palache, C., Berman, H., Frondel, C. (1944) The System of Mineralogy of James Dwight Dana and Edward Salisbury Dana Yale University 1837-1892, Volume I: Elements, Sulfides, Sulfosalts, Oxides. John Wiley and Sons, Inc., New York. 7th edition, revised and enlarged, 834pp.: 178-179.
Main, J.V., Rodgers, K.A., Kobe, H.W., Woods, C.P. (1972) Aguilarite from the Camoola Reef, Maratoto Valley, New Zealand. Mineralogical Magazine: 38: 961-964.
Petruk, W., Owens, D.R., Stewart, J.M., Murray, E.J. (1974) Observations on acanthite, aguilarite and naumannite. The Canadian Mineralogist: 12: 365-369.
Pingitore, N.E., Ponce, B.F., Eastman, M.P., Moreno, F., Podpora, C. (1992) Solid solutions in the system Ag2S-Ag2Se. Journal of Material Research: 7: 2219-2224.
Pingitore, N.E., Ponce, B.F., Estrada, L., Eastman, M.P., Yuan, H.L., Porter, L.C., Estrada, G. (1993) Calorimetric analysis of the system Ag2S-Ag2Se between 25 and 250°C. Journal of Material Research: 8: 3126-3130.
Bindi, L., Pingitore, N.E. (2013) On the symmetry and crystal structure of aguilarite, Ag4SeS. Mineralogical Magazine: 77: 21-31.
Seryotkin, Y.V., Palyanova, G.A., Kokh, K.A. (2015): Sulfur-selenium isomorphous substitution and polymorphism in the Ag2(S,Se) series. Journal of Alloys and Compounds 639, 89-93.
Števko M., Sejkora J., Dolníček Z., Škácha P. (2018): Selenium-rich Ag–Au mineralization at the Kremnica Au–Ag epithermal deposit, Slovak Republic. Minerals 12(8), 572.
Kullerud, K., Kotková, J., Šrein, V., Drábek, M., Škoda, R. (2018): Solid solutions in the system acanthite (Ag2S)–naumannite (Ag2Se) and the relationships between Ag-sulfoselenides and Se-bearing polybasite from the Kongsberg silver district, Norway, with implications for sulfur–selenium fractionation. Contributions to Mineralogy and Petrology Article 173, 71.

Internet Links for AguilariteHide

Localities for AguilariteHide

This map shows a selection of localities that have latitude and longitude coordinates recorded. Click on the symbol to view information about a locality. The symbol next to localities in the list can be used to jump to that position on the map.

Locality ListHide

- This locality has map coordinates listed. - This locality has estimated coordinates. ⓘ - Click for further information on this occurrence. ? - Indicates mineral may be doubtful at this locality. - Good crystals or important locality for species. - World class for species or very significant. (TL) - Type Locality for a valid mineral species. (FRL) - First Recorded Locality for everything else (eg varieties). Struck out - Mineral was erroneously reported from this locality. Faded * - Never found at this locality but inferred to have existed at some point in the past (eg from pseudomorphs.)

All localities listed without proper references should be considered as questionable.
Argentina
 
  • La Rioja Province
    • General Lamadrid department
Canadian Mineralogist Vol. 42, 1745-1755 (2004).
Australia
 
  • New South Wales
    • Auckland Co.
Handbook of Mineralogy
  • Western Australia
    • Kalgoorlie-Boulder Shire
      • Kalgoorlie-Boulder
Simpson, E.S. (1948), Minerals of Western Australia, Vol 1, State Government of Western Australia, pp 1-2, 1948
Simpson, E.S. (1948), Minerals of Western Australia, Vol 1, pp40, 1948
Simpson, E.S. (1948), Minerals of Western Australia, Vol 1, pp 40, 1948
Simpson, E.S. (1948), Minerals of Western Australian, Vol 1, pp 40, 1948
      • Mulgabbie Goldfield
Simpson, E.S. (1948), Minerals of Western Australia, Vol 1, pp 2, 1948
Bulgaria
 
  • Pazardzhik Province
    • Panagyurishte (Panagurishte) Obshtina
      • Panagyurishte
Cioacă, M. E., Ivanov, D., Iorga-Pavel, A., Stoilov, V., Milu, V., Barbu, O., ... & Munteanu, M. (2018). Au-Ag-Bi mineralization at the Assarel porphyry copper deposit (Srednogorie metallogenic zone, Bulgaria). Advances of Geology in southeast European mountain belts, 276.
Canada
 
  • British Columbia
    • Clinton Mining Division
British Columbia Ministry of Energy, Mines and Petroleum Resources, Geological Fieldwork, 1986, Paper 1987-1, pp. 15-22
    • Liard Mining Division
      • Iskut River
Rhys, D.A. (1993): Geology of the Snip mine and its relationship to the magmatic and deformational history of the Johnny Mountain area, northwestern British Columbia. The University of British Columbia, unpublished M.Sc. thesis, 1993, 278 pp.
  • Ontario
    • Sudbury District
      • Wisner Township
Péntek, A., Molnár, F., Tuba, G., Watkinson, D. H., & Jones, P. C. (2013). The significance of partial melting processes in hydrothermal low sulfide Cu-Ni-PGE mineralization within the footwall of the Sudbury Igneous Complex, Ontario, Canada. Economic Geology, 108(1), 59-78.
Chile
 
  • Antofagasta
    • Antofagasta Province
      • Antofagasta
Arfè, G., Boni, M., Mondillo, N., Aiello, R., Balassone, G., Arseneau, V. and Soyk, D. (2016): Supergene alteration in the Capricornio Au-Ag epithermal vein system, Antofagasta Region, Chile. Can. Mineral. 54, 681-706.
China
 
  • Hubei
    • Yichang
      • Xingshan Co.
Chao Chen and Fapeng Xie (1986): Mineral Deposits 5(1), 53-62; Tianwei Guo and Zhongwen Han (1990): Northeastern Geological Science and Technology Information 11(2), 1-11
  • Inner Mongolia
    • Chifeng City (Ulanhad League; Chifeng Prefecture)
      • Bairin Left Banner (Balin Zuoqi)
Yongsheng Kuang, Guangrui Zheng, Minjie Lu, Yanlin Liu, Shaojie Zhang, Ruiyang Li, and Wenjing Cheng (2014): Mineral Deposits 33(4), 847-856
    • Hulunbuir City (Hulunbei'er Prefecture)
      • New Barag Right Banner (Xin Barag Youqi)
Zhicheng Lü, Paiping Zhang, Guozheng Duan, Libo Hao, and Guanghua Dong (2002): Journal of Mineralogy and Petrology 22(1), 1-5; Zhicheng Lu, Peiping Zhang, Guozheng Duan, Libo Hao, and Dianchao Li (2002): Acta Mineralogica Sinica 22(1), 75-80; Jingxian Li and Jiajun Liu (2014): Resources & Industries 16(2), 90-97
  • Jiangxi
    • Fuzhou
      • Dongxiang Co.
Xia Ai and Zengyi Chen (1993): Geology and Prospecting 29(4), 25-29
  • Sichuan
    • Liangshan
      • Huili County
Dong Zhensheng et al. (1996). In: Tu Guangzhi, Ed.: Low Temperature Geochemistry, Science Press (Beijing), 32-42.
Czech Republic
 
  • Central Bohemian Region
    • Kutná Hora District
      • Poličany
Pažout, R., Sejkora, J., & Šrein, V. (2019). Ag-Pb-Sb Sulfosalts and Se-rich Mineralization of Anthony of Padua Mine near Poličany—Model Example of the Mineralization of Silver Lodes in the Historic Kutná Hora Ag-Pb Ore District, Czech Republic. Minerals, 9(7), 430.
  • South Bohemian Region
    • Písek District
      • Kovářov
        • Předbořice
Bindi, L., Förster, H. J., Grundmann, G., Keutsch, F., & Stanley, C. (2016). Petříčekite, CuSe2, a New Member of the Marcasite Group from the Předbořice Deposit, Central Bohemia Region, Czech Republic. Minerals, 6(2), 33.
  • Vysočina Region
    • Žďár nad Sázavou District
      • Nové Město na Moravě
Vavřín, I.: Nové poznatky o selenidech Českého masívu. Bulletin Mineralogicko-petrografického oddělení Národního muzea v Praze, 1994, roč. 2, s. 82-89.
Indonesia
 
  • Banten Province
Yuningsih, E. T., Matsueda, H., & Rosana, M. F. (2014). Epithermal Gold-Silver Deposits in Western Java, Indonesia: Gold-Silver Selenide-Telluride Mineralization. Indonesian Journal on Geoscience, 1(2), 71-81.
    • Cikotok Gold District
Yuningsih, E. T., Matsueda, H., & Rosana, M. F. (2014). Epithermal Gold-Silver Deposits in Western Java, Indonesia: Gold-Silver Selenide-Telluride Mineralization. Indonesian Journal on Geoscience, 1(2), 71-81.
  • Bengkulu Province
    • Rejang Lebong District (Rediang Lebong District)
Econ Geol (1997) 92:468-484
  • West Java Province
    • Bogor Regency
Milési, J.P., Marcoux, E., Sitorus, T., Simandjuntak, M., Leroy, J., and Bailly, L. (1999): Mineralium Deposita 34, 131-149.; The Canadian Mineralogist Vol. 41, pp. 185-200 (2003); Yuningsih, E. T., Matsueda, H., & Rosana, M. F. (2014). Epithermal Gold-Silver Deposits in Western Java, Indonesia: Gold-Silver Selenide-Telluride Mineralization. Indonesian Journal on Geoscience, 1(2), 71-81.
Yuningsih, E. T., Matsueda, H., & Rosana, M. F. (2014). Epithermal Gold-Silver Deposits in Western Java, Indonesia: Gold-Silver Selenide-Telluride Mineralization. Indonesian Journal on Geoscience, 1(2), 71-81.
    • Sukabumi Regency
Yuningsih, E. T., Matsueda, H., & Rosana, M. F. (2014). Epithermal Gold-Silver Deposits in Western Java, Indonesia: Gold-Silver Selenide-Telluride Mineralization. Indonesian Journal on Geoscience, 1(2), 71-81.
    • Tasikmalaya Regency
Yuningsih, E. T., Matsueda, H., & Rosana, M. F. (2014). Epithermal Gold-Silver Deposits in Western Java, Indonesia: Gold-Silver Selenide-Telluride Mineralization. Indonesian Journal on Geoscience, 1(2), 71-81.
Iran
 
  • Sistan and Baluchestan Province
    • Iranshahr County
      • Bazman Volcano
DALIRAN, F., PAAR, W.H., NEUBAUER, F., RASCHIDI, B. (2005): New Discovery of Epithermal Gold at Chahnali Prospect, Bazman Volcano, SE-Iran. In: Mao, J. & Bierlein, F. P. (eds.): Mineral deposit research: Meeting the global challenge. Springer, Berlin – Heidelberg, 917–919.
Japan
 
  • Fukuoka prefecture
    • Munakata
Matsukuma, T. (1962) Journal of the Mining College, Akita University, Series A, Mining Geology, 2, #2, 26-27.
  • Fukushima
    • Koriyama
Econ Geol (1985) 80:1415-1424
  • Hokkaidō
    • Hidaka Subprefecture
      • Monbetsu (Mombetsu)
Tharalson, E.R.; Monecke, T.; Reynolds, T.J.; Zeeck, L.; Pfaff, K.; Kelly, N.M. (2019) The Distribution of Precious Metals in High-Grade Banded Quartz Veins from Low-Sulfidation Epithermal Deposits: Constraints from µXRF Mapping. Minerals 9, 740.
    • Ishikari Subprefecture
Mineral.Journ.Japan (1985) 12, 341-348; Economic Geology 93 (1998) 303-325.
    • Kamikawa Subprefecture
      • Shimokawa
Sugaki et al (1982) Journal of the Japan Association of Mineralogists, Petrologists and Economic Geologists, 77, 65-77.; Econ Geol (1985) 80:1415-1424
    • Soya Subprefecture
      • Esashi-gun
        • Esashi-cho
          • Utanobori
            • Pankenai
Yamada, S. (2004) Nihonsan-koubutsu Gojuon-hairetsu Sanchi-ichiranhyou (111 pp.)
  • Hyogo
    • Toyooka City
Econ Geol (1985) 80:1415-1424
  • Kagoshima
Morishita, Y., Hammond, N. Q., Momii, K., Konagaya, R., Sano, Y., Takahata, N., & Ueno, H. (2019). Invisible Gold in Pyrite from Epithermal, Banded-Iron-Formation-Hosted, and Sedimentary Gold Deposits: Evidence of Hydrothermal Influence. Minerals, 9(7), 447.
Fulin Zhang, Chengmo Jin, and Qiyun Qing (1986): Geology and Prospecting 22(6), 9-12
    • Kushikino City
Econ Geol (1985) 80:1415-1424
    • Okuchi City
      • Okuchi mine (Oguchi mine)
Econ Geol (1985) 80:1415-1424
  • Okayama
    • Ibara City
      • Higashi-Mihara
        • Mihara mine
Econ Geol (1985) 80:1415-1424
Mexico
 
  • Guanajuato
    • Guanajuato Municipality
      • Guanajuato
Solana Espinosa, Gabriel; Cervantes Lee, Francisco Jose; Zarate del Valle, Pedro Faustino (1986): Mineralogical study of silver ores from "El Cubo" mine in Guanajuato, Mexico. Revista de la Sociedad Quimica de Mexico 30(2), 66-69.
Marko Burkhardt collection
- Cook, R. B. (1999). Who's Who in Mineral Names : People after Whom Mexican Minerals Have Been Named. Rocks & Minerals, Vol. 74, 1, Pages 44-50. East. Fed. Min. Lap. & Midw. Fed. Min. Geol. Soc.
      • La Luz
Can Min 12 (1974), 365; Clark, 1993 - "Hey's Mineral Index, 3rd Edition"; Panczner (1987): 86.
Panczner (1987): 86.
      • Nayal
Panczner(1987):87.
      • Rayas
Panczner(1987):86.
  • Guerrero
    • Taxco de Alarcón
Panczner(1987):80,86.
  • Zacatecas
Robertson, J., Siepka, A., and Wells, P, 2009, Valdecanas Project-Scoping Study Technical Report. Report prepared for Minera Juanicipio JV, by Wardrop Engineering, August 20, 2009. Available on SEDAR; Peter Megaw
New Zealand
 
  • Auckland Region
Railton, G.T., Watters, W.A. (1990) Minerals of New Zealand. New Zealand Geological Survey Bulletin 104, 89 pages.
Christie, A.B., Mauk, J.L., Simpson, M.P., Brathwaite, R.L., Simmons, S.F. (2007) Epithermal Au-Ag and Related Deposits of the Hauraki Goldfield, Coromandel Volcanic Zone, New Zealand. Economic Geology, 102:5, 785-816.
Econ Geol (1997) 92:468-484
  • Waikato Region
    • Hauraki District
      • Paeroa
Railton, G.T., Watters, W.A. (1990) Minerals of New Zealand. New Zealand Geological Survey Bulletin 104, 89 pages. Simon, G., Kesler, S.E., Essene, E.J. (1997) Phase relations among selenides, tellurides, and oxides; II, Applications to selenide-bearing ore deposits. Economic Geology, 92, 468-484.
Handbook of Mineralogy
Moore, C.R. (1979) Geology and mineralisation of the former Broken Hills gold mine, Hikuai, Coromandel, New Zealand. New Zealand Journal of Geology and Geophysics, 22:3, 339-351, at p346.
      • Waihi
Simpson, M.P., Mauk, J.L. (2007) The Favona epithermal gold-silver deposit, Waihi, New Zealand. Economic Geology 102, 817-839.
Simpson, M. P., & Mauk, J. L. (2011). Hydrothermal alteration and veins at the epithermal Au-Ag deposits and prospects of the Waitekauri area, Hauraki goldfield, New Zealand. Economic Geology, 106(6), 945-973.
    • Thames-Coromandel District
      • Coromandel peninsula
Fitzgerald, M.J. (2004) Gold mineralisation at Ohui eastern coromandel (unpublished thesis, MSc), University of Waikato.
      • Hikuai
Railton, G.T., Watters, W.A. (1990) Minerals of New Zealand. New Zealand Geological Survey Bulletin 104, 89 pages. Cocker, H.A., Mauk, J.L., Rabone, S.D.C. (2013) The origin of Ag-​Au-​S-​Se minerals in adularia-​sericite epithermal deposits: constraints from the Broken Hills deposit, Hauraki Goldfield, New Zealand. Mineralium Deposita, 48:2, 249-266.
Norway
 
  • Buskerud
    • Flesberg
      • Vinoren Silver Mine Field
        • Vinoren Southern Mines
Kåre Kullerud information; Larsen, K. E. (2015). Noen funn av mineraler i Norge 2013-2015. Norsk Mineralsymposium 2015, 79-88.
Panama
 
  • Veraguas Province
Byington, C.B. and Russell, M.R., 2001, Economic geology and ore controls of the Santa Rosa Mine – An integrated structural analysis approach, Canazas, Veraguas, Republic of Panama: Society of Economic Geologists Special Publication 8, p. 318-329.
Russia
 
  • Chukotka Autonomous Okrug
    • Chukchi Peninsula (Chukotka Peninsula; Chukotski Peninsula)
Nokleberg, Warren J. et al (2005) Metallogenesis and tectonics of the Russian Far East, Alaska, and the Canadian Cordillera. USGS Professional Paper 1697
    • Okhotsk-Chukotka belt
http://www.infomine.com/press_releases/wpn/pr111097wpn.html; Sidorov, A. A., & Eremin, R. A. (1994). Metallogeny and gold lode deposits of northeastern Russia. ICAM-94 proceedings, 247-256.
  • Kamchatka Krai
Takahashi, Ryohei; Natsueda, Hiroharu; Okrugin, Victor M.; Ono, Shuji (2007): Epithermal gold-​silver mineralization of the Asachinskoe deposit in southern Kamchatka, Russia. Resource Geology 57(4), 354-373.
    • Penzhina Bay
      • Penzhina River
Anthony, Bideaux, Bladh, Nichols: "Handbook of Mineralogy", Vol. 1, 1990; Pekov, I. (1998) Minerals First discovered on the territory of the former Soviet Union 369p. Ocean Pictures, Moscow
Takahashi, R., Matsueda, H., & Okrugin, V. M. (2002). Hydrothermal gold mineralization at the Rodnikovoe deposit in South Kamchatka, Russia. Resource Geology, 52(4), 359-369.
  • Krasnoyarsk Krai
    • Taymyrskiy Autonomous Okrug
      • Taimyr Peninsula
        • Putoran Plateau
(2014) 12th International Platinum Symposium p320
  • Magadan Oblast
Savva, N. E., & Pal’yanova, G. A. (2007). Genesis of gold and silver sulfides at the Ulakhan deposit (northeastern Russia). Russian Geology and Geophysics, 48(10), 799-810.
Slovakia
 
  • Banská Bystrica Region
    • Žiar nad Hronom Co.
Števko M., Sejkora J., Dolníček Z., Škácha P. (2018): Selenium-Rich Ag–Au Mineralization at the Kremnica Au–Ag Epithermal Deposit, Slovak Republic. Minerals 8, 12, 572.
Sweden
 
  • Värmland County
    • Grums
      • Värmskog
Nysten, C. Malmmineralogisk undersökning av Pb-, Zn-, Cu- och Ag-förande kvartsgångar i Värmskogsområdet, mellersta Värmland. Uppsala universitet, Institutionen för geovetenskaper. Examensarbete NV3, Berggrundsgeologi, 30 hp. nr 254. 107p.
USA
 
  • California
    • Inyo Co.
      • Inyo Mts (Inyo Range)
        • Malpais Mesa
Adams, P.M. (2016): Sulfide, selenium and rare earth mineralization in the Sulfate Stope, Santa Rosa Mine, Inyo County, California. 2016 Desert Symposium Field Guide and Proceedings, California State University, Desert Studies Consortium, 244-252.; Paul M. Adams (2017) The Santa Rosa mine, Inyo County, California. Minerlogical Record 48:755-777
  • Colorado
    • Hinsdale Co.
      • Lake City Mining District (Lake Mining District)
        • Lake City
Minerals of Colorado (1997) Eckels, E. B.
  • Idaho
    • Custer Co.
R&M 70:4 pp 242-263
Ream, L.R., "Idaho Minerals," pg. 99, 1989, LR Ream Publishing, Coeur d'Alene, Idaho, USA in part. Additionally from the RO Meyer collection.
    • Owyhee Co.
R&M 70:4 pp 242-263
Ream, Lanny R. 2004. Idaho Minerals, 2nd edition, Revised and Updated; Can Mineral 1981 19: 409-410
Econ Geol (1997) 92:468-484
Collins, A. (2012) Geology, Geochemistry and Geochronology of the mid-Miocene, Low-Sulfidation Epithermal Gold-Silver Ores on War Eagle Mountain, Silver City District, Idaho. MS thesis Auburn University, Alabama.
        • War Eagle Mine (South Chariot; Orofino; Golden Chariot; Mahogany; Sinker; Ida Elmore)
Collins, A. (2012) Geology, Geochemistry and Geochronology of the mid-Miocene, Low-Sulfidation Epithermal Gold-Silver Ores on War Eagle Mountain, Silver City District, Idaho. MS thesis Auburn University, Alabama.
  • Nevada
    • Elko Co.
      • Gold Circle Mining District (Midas Mining District)
NBMG Spec. Pub. 31 Minerals of Nevada
LEAVITT, Ellen D., (2005) PARAGENESIS AND DISTRIBUTION OF TRACE ELEMENTS, REES, AND STABLE ISOTOPES OF EPITHERMAL AU-AG VEINS, KEN SNYDER MINE, MIDAS, NEVADA GSA 2005 Salt Lake City Annual Meeting (October 16–19, 2005) ; Economic Geology (2004) Vol. 99, pp. 1665–1686.
Leavitt, E. D., Spell, T. L., Goldstrand, P. M., & Arehart, G. B. (2004). Geochronology of the Midas low-sulfidation epithermal gold-silver deposit, Elko County, Nevada. Economic Geology, 99(8), 1665-1686.; Tharalson, E.R.; Monecke, T.; Reynolds, T.J.; Zeeck, L.; Pfaff, K.; Kelly, N.M. (2019) The Distribution of Precious Metals in High-Grade Banded Quartz Veins from Low-Sulfidation Epithermal Deposits: Constraints from µXRF Mapping. Minerals 9, 740.
    • Humboldt Co.
      • Awakening Mining District
NBMG Spec. Pub. 31 Minerals of Nevada
    • Lander Co.
      • Lewis Mining District
NBMG Spec. Pub. 31 Minerals of Nevada
      • Shoshone Mts
U.S. Geological Survey, 2005, Mineral Resources Data System: U.S. Geological Survey, Reston, Virginia.
    • Mineral Co.
      • Rawhide Mining District
NBMG Spec. Pub. 31 Minerals of Nevada
    • Nye Co.
      • Kawich Range
        • Silver Bow Mining District (Silverbow Mining District)
NBMG Spec. Pub. 31 Minerals of Nevada
          • Nixon Peak
NBMG Spec. Pub. 31 Minerals of Nevada
          • Silverbow
NBMG Spec. Pub. 31 Minerals of Nevada
      • San Antonio Mts
NBMG Spec. Pub. 31 Minerals of Nevada
      • Toquima Range
        • Round Mountain Mining District
          • Round Mountain
Bart Cannon EDS of RWMW specimen
    • Storey Co.
NBMG Spec. Pub. 31 Minerals of Nevada
        • Virginia City
Econ Geol (1997) 92:468-484
  • New Mexico
    • Sierra Co.
      • Winston
Handbook of Mineralogy
  • Utah
    • Washington Co.
      • Leeds
UGMS Bull 117 Minerals and Mineral Localities of Utah
  • Washington
    • Chelan Co.
      • Wenatchee Mining District
        • Wenatchee
          • Squillchuck Creek
Lasmanis, R. Et Al (1990): Metal Mines of Washington-Preliminary Report, p.9
Cannon, B. (1975): Minerals of Washington, p.37, 103, 128; Lasmanis, R. Et Al (1990): Metal Mines of Washington-Preliminary Report, p.14
    • Ferry Co.
      • Republic Mining District
        • Republic
          • Klondike Mountain
Cannon, B. (1975): Minerals of Washington' p.35, 37, 64, 136, 161
Uzbekistan
 
  • Navoiy
    • Central Kyzylkum Region
      • Bel'tau Mts
Koneev, R.I., Turesebekov, A.H., Ignatikov, E.N., Vasilevsky, B.B., and Rakhimov, R.R. (2005), In: Jingwen Mao and Bierlein, F.P. (Eds.): Mineral Deposit Research: Meeting the Global Challenge, Vol. 1, 1403-1406
      • Zarafshan
        • Muruntau ore field
Koneev, R.I., Turesebekov, A.H., Ignatikov, E.N., Vasilevsky, B.B., and Rakhimov, R.R. (2005), In: Jingwen Mao and Bierlein, F.P. (Eds.): Mineral Deposit Research: Meeting the Global Challenge, Vol. 1, 1403-1406
Koneev, R.I., Turesebekov, A.H., Ignatikov, E.N., Vasilevsky, B.B., and Rakhimov, R.R. (2005), In: Jingwen Mao and Bierlein, F.P. (Eds.): Mineral Deposit Research: Meeting the Global Challenge, Vol. 1, 1403-1406
  • Tashkent
    • Chatkal-Kuraminskii Range
Rustam Koneev, Evgeniy Ignatikov, Arpay Turesebekov, Umid Aripov, Rustam Khalmatov, Obidjon Kodirov, Miraziz Usmanov (2005) Gold ore deposits of Uzbekistan: Geochemistry and nanomineralogy of tellurium and selenium. IGCP Project 486, 2005 Field Workshop, Kiten, Bulgaria, 14-19 September 2005
 
矿物 and/or 产地  
版权所有© mindat.org1993年至2020年,除了规定的地方。 Mindat.org全赖于全球数千个以上成员和支持者们的参与。
隐私政策 - 条款和条款细则 - 联络我们 Current server date and time: 2020.1.27 14:41:32 Page generated: 2020.1.8 12:59:23
Go to top of page