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Items: 1 to 20 of 110

1.

Anomalously metal-rich fluids form hydrothermal ore deposits.

Wilkinson JJ, Stoffell B, Wilkinson CC, Jeffries TE, Appold MS.

Science. 2009 Feb 6;323(5915):764-7. doi: 10.1126/science.1164436.

2.

The origin of Cu/Au ratios in porphyry-type ore deposits.

Halter WE, Pettke T, Heinrich CA.

Science. 2002 Jun 7;296(5574):1844-6.

3.

Gold solubility in supercritical hydrothermal brines measured in synthetic fluid inclusions

Loucks RR, Mavrogenes JA.

Science. 1999 Jun 25;284(5423):2159-63.

4.
5.

Hydrothermal alteration and Cu-Ni-PGE mobilization in the charnockitic rocks of the footwall of the South Kawishiwi intrusion, Duluth Complex, USA.

Benkó Z, Mogessie A, Molnár F, Krenn K, Poulson SR, Hauck S, Severson M, Arehart GB.

Ore Geol Rev. 2015 Jun;67:170-188.

6.

The structure and dynamics of mid-ocean ridge hydrothermal systems.

Coumou D, Driesner T, Heinrich CA.

Science. 2008 Sep 26;321(5897):1825-8. doi: 10.1126/science.1159582.

7.

Raman and micro-thermometric investigation of the fluid inclusions in quartz in a gold-rich formation from Lepaguare mining district (Honduras, Central America).

Bersani D, Salvioli-Mariani E, Mattioli M, Menichetti M, Lottici PP.

Spectrochim Acta A Mol Biomol Spectrosc. 2009 Aug;73(3):443-9. doi: 10.1016/j.saa.2008.10.046. Epub 2008 Nov 7.

PMID:
19117796
8.

How metalliferous brines line Mexican epithermal veins with silver.

Wilkinson JJ, Simmons SF, Stoffell B.

Sci Rep. 2013;3:2057. doi: 10.1038/srep02057.

9.

Melt inclusions in veins: linking magmas and porphyry Cu deposits.

Harris AC, Kamenetsky VS, White NC, van Achterbergh E, Ryan CG.

Science. 2003 Dec 19;302(5653):2109-11.

10.

Atmospheric sulfur in Archean komatiite-hosted nickel deposits.

Bekker A, Barley ME, Fiorentini ML, Rouxel OJ, Rumble D, Beresford SW.

Science. 2009 Nov 20;326(5956):1086-9. doi: 10.1126/science.1177742.

11.

Lithium isotope traces magmatic fluid in a seafloor hydrothermal system.

Yang D, Hou Z, Zhao Y, Hou K, Yang Z, Tian S, Fu Q.

Sci Rep. 2015 Sep 8;5:13812. doi: 10.1038/srep13812.

12.

Neutron Activation Analysis of Fluid Inclusions for Copper, Manganese, and Zinc.

Czamanske GK, Roedder E, Burns FC.

Science. 1963 Apr 26;140(3565):401-3.

PMID:
17815804
13.

Precipitation of sulfide ores and organic matter: sulfate reactions at pine point, Canada.

Powell TG, Macqueen RW.

Science. 1984 Apr 6;224(4644):63-6.

PMID:
17783525
14.

Survival times of anomalous melt inclusions from element diffusion in olivine and chromite.

Spandler C, O'Neill HS, Kamenetsky VS.

Nature. 2007 May 17;447(7142):303-6.

PMID:
17507980
15.

Fluid inclusion studies of chemosynthetic carbonates: strategy for seeking life on Mars.

Parnell J, Mazzini A, Honghan C.

Astrobiology. 2002 Spring;2(1):43-57.

PMID:
12449854
16.

Porphyry-copper ore shells form at stable pressure-temperature fronts within dynamic fluid plumes.

Weis P, Driesner T, Heinrich CA.

Science. 2012 Dec 21;338(6114):1613-6. doi: 10.1126/science.1225009. Epub 2012 Nov 15.

18.

[Spectral characteristics and implications of quartz from Heliao lead-zinc polymetallic ore district in the south of Qinzhou-Hangzhou joint belt].

Lü WC, Yang ZJ, Zhou YZ, Li HZ, Zeng XQ, Chen Q, Liang J, Zeng CY.

Guang Pu Xue Yu Guang Pu Fen Xi. 2013 May;33(5):1374-8. Chinese.

PMID:
23905355
19.

Comparison of bioleaching behaviors of different compositional sphalerite using Leptospirillum ferriphilum, Acidithiobacillus ferrooxidans and Acidithiobacillus caldus.

Xia L, Dai S, Yin C, Hu Y, Liu J, Qiu G.

J Ind Microbiol Biotechnol. 2009 Jun;36(6):845-51. doi: 10.1007/s10295-009-0560-9. Epub 2009 Mar 31.

PMID:
19333635
20.

Multiple ion association in supercritical aqueous solutions of single electrolytes.

Oelkers EH, Helgeson HC.

Science. 1993 Aug 13;261(5123):888-91.

PMID:
17783734
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