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Ore textures: problems and opportunities

Published online by Cambridge University Press:  05 July 2018

Paul B. Barton Jr.
Paul B. Barton Jr.*
Affiliation:
959 U.S. Geological Survey, Reston, Virginia 22092, U.S.A.
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Abstract

Over the past several decades, thinking about chemical processes in rocks had been dominated by experimental and theoretical treatments of mineral equilibrium, which is the state from which the time variable has been excluded. But, to an extent exceeding that of any of our sister sciences, we in geology are concerned with the behaviour of things as a function of time; thus equilibrium is but one of several interesting boundary conditions. Textures, (defined as the spatial relations within and among minerals and fluids, regardless of scale or origin) provide a means to sort out and identify successive states. In fact, it is the pattern of evolution of those states that enables us to deduce the processes. We may well draw the analogy with thermodynamics and kinetics, respectively:

equilibrium textures and phase assemblages, via thermodynamic analysis → definition of conditions of equilibration,

whereas

kinetics, as displayed in disequilibrium textures → sequence of events and processes of mineralization.

The interpretation of textures is one of the most difficult yet important aspects of the study of rocks and ores, and there are few areas of scientific endeavour that are more subject to misinterpretation. Although the difficulties are many, the opportunites for new understanding are also abundant. Textural interpretations have many facets: some are well established and accepted; some that are accepted may be wrong; others are recognised to be speculative and controversial; and we trust that still other textural features remain to be described and interpreted. This paper will deal principally with low-temperature, epigenetic ore deposits, and will emphasise silica and sphalerite; but extension to other materials is not unreasonable.

Ore and gangue minerals react internally, or with their environment, at widely ranging rates, ranging from the almost inert pyrite, arsenopyrite, well-crystallised quartz, and tourmaline to the notoriously fickle copper/iron and copper/silver sulfides. Arrested or incomplete reactions may be identifed by textural criteria and, when appropriately quantified, can provide guides to the duration of geological processes.

In recent years so much emphasis has been placed on isotopes, fluids, chemistry, and deposit and process models that the textural features have been ignored. In part this oversight occurs because we have grown accustomed to using superposition, cross-cutting, pseudomorphism, mutual intergrowths, exsolution and so on as off-the-shelf tools, to be grasped and applied without evaluation or even description. Surely science must build on previous work without constant and exhaustive reassessment, but for mineral textures a little reassessment may yield substantial benefit.

Keywords

ore depositstexturesphase assemblagessilicasphalerite
Type
Research Article
Information
Mineralogical Magazine , Volume 55 , Issue 380 , September 1991 , pp. 303 - 315
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 1991

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References

Barton, P. B. Jr., (1970) Sulfide petrology. Mineral. Soc. Am. Special Paper 3, 187-98.Google Scholar
Barton, P. B. Jr., (1978) Some ore textures involving sphalerite from the Furutobc mine, Akita Pref., Japan. Mining Geol., 28. 298300.Google Scholar
Barton, P. B. Jr., and Bethke, P. M. (1987) Chalcopyrite disease in sphalerite: pathology and epidemiology. Am. Mineral. , 72, 451-67.Google Scholar
Barton, P. B. Jr., and Skinner, B. J. (1979) Sulfide mineral stabilities. In Geochemistry of Hydrothermal ore Deposits (H. L., Barnes, ed.), 278-03, Wiley-Interscience, New York.Google Scholar
Barton, P. B. Jr., , Bethke, P. M., and Toulmin, P. III (1963) Equilibrium in ore deposits. Mineral. Soc. Am. Spec. Paper 1, 171-85.Google Scholar
Barton, P. B. Jr., , Bethke, P. M., and Toulmin, M. (1971) An attempt to determine the vertical component of flow rate of ore-forming solutions in the OH vein, Creede, Colarado. Soc. Mining Geol. Japan, Special Issue 2, 132–6.Google Scholar
Barton, P. B. Jr., , Bethke, P. M., and Rocdder, E. (1977) Environment of ore deposition in the Creede mining district, San Juan Mountains, Colorado: Part III. Progress toward interpretation of the chemistry of the ore-forming fluid for the OH vein. Econ. Geol., 72, 124.CrossRefGoogle Scholar
Bethke, P. M. and Barton, P. B. Jr., (1971) Distribution of some minor elements between coexisting sulfide minerals. Ibid., 66, 140-63.Google Scholar
Bethke, P. M. and Rye, R. O. (1979) Environment of ore deposition in the Creede mining district, San Juan Mountains, Colorado: Part IV. Source of fluids from oxygen, hydrogen and carbon isotope studies. Ibid., 74, 1832-51.Google Scholar
Campbell, W. and Knight, C. W. (1906) A microscopic examination of the cobalt-nickel arsenides and silver deposits of Timiskaming. Ibid., 1, 751-66.Google Scholar
Clendenin, C. W. (1977) Suggestions for interpreting Viburnum Trend mineralization based on field studies at Ozark Lead Company, southeast Missouri. Ibid., 72, 465-73.Google Scholar
Donnay, J. D. H. (1930) Thinned polished sections. Ibid., 25, 270–4.Google Scholar
Eldridge, C. S., Barton, P. B. Jr., , and Ohmoto, H. (1983) Mineral textures and their bearing on the formation of the Kuroko orebodies. Economic Geology Mongraph 5, 241-81.Google Scholar
Eldridge, C. S., Bourcier, W. L., Ohmoto, H., and Barnes, H. L. (1988) Hydrothermal inoculation and incubation of the chalcopyrite disease in sphalerite. Econ. Geol., 83, 978-89.CrossRefGoogle Scholar
Fournier, R. O. (1967) The porphyry copper exposed in the Liberty Open-Pit Mine near Ely, Nevada. Part II. The formation of hydrothermal alteration zones. Ibid., 62, 207-27.Google Scholar
Fournier, R. O. (1985) The behavior of silica hydrothermal systems. Chapter 3 in Geology and Geochemstry of Epithermal Systems (B. R. Berger and P. M. Bethke, eds.) Economic Geology Publishing Company, 4561.Google Scholar
Gruner, J. W. (1933) The solubilities of metallic sulfides in alkali sulfide solutions. Econ. Geol, 28, 773–7.CrossRefGoogle Scholar
Heald-Wetlaufer, P., Foley, N. K., and Hayba, D. O. (1982) Applications of doubly polished sections to the study of ore deposits: p. 451-4-68 in Process Metallurgy II: Applications in Metallurgy, Ceramics and Geology (R. D. Hagni, ed.) Metall. Soc, AIME.Google Scholar
Hutchinson, M. N. and Scott, S. D. (1981) Sphalerite geobarometry in the system Cu-Fe-Zn-S. Econ. Geol., 76, 143-53.CrossRefGoogle Scholar
Kojima, S. and Sugaki, A. (1984) Phase relations in the central portion of the Cu-Fe-Zn-S system between 800° and 500°C Mineral. J., 123, 1528.Google Scholar
Kojima, S. and Sugaki, A. (1985) Phase relations in the Cu-Fe-Zn-S system between 500°C and 300°C under hydrothermal conditions. Econ. Geol., 80, 158-71.CrossRefGoogle Scholar
Kopp, O. C., Ebers, M. L., Cobb, L. B., Crattie, T. B., Ferguson, T. L., Larson, R. M., Potosky, R. A., and Steinberg. R. T. (1986) Application of cathodolumi-nescence microscopy to the study of gangue carbonates in the Mississippi Valley-type deposits in Tennessee: the search for a ‘Tennessee Trend': p. 53-67 in Process Mineralogy VI (R. D. Hagni, ed.) Metall. Soc, AIME.Google Scholar
Korzhinskii, D. S. (1959) Physiochemical Basis of the Analysis of the Paragenesis of Minerals (English translation). Consultants Bureau, New York, 1452 pp.Google Scholar
Lovering, T. G. (1972) Jasperoid in the United States-Its Characteristics, Origin, and Economic Significance. U.S. Geological Survey Professional Paper 710, 164 pp.Google Scholar
McLimans, R. K., Barnes, H. L., and Ohmoto, H. (1980) Sphalerite stratigraphy of the upper Missis-sippi Valley zinc-lead district, southwest Wisconsin. Econ. Geol., 75, 351-61.Google Scholar
Mizuta, T. (1988) Interdiffusion rate of zinc and iron in natural sphalerite. Ibid., 83, 1205-20.Google Scholar
Ohashi, R. (1919) On the origin of kuroko of the Kosaka mine. Geol. Soc. Japan Journal, 26, 107-32 (in Japanese).Google Scholar
Plumlee, G. S. (1989) Processes Controlling Epithermal Mineral Distribution in the Creede Mining District, Colorado. PhD Thesis, Harvard University, 378 pp.Google Scholar
Ramdohr, Paul. (1960) Die Erzmineralien und ihre Verwachsungen. Akademie Verlag, Berlin, 1089 pp. Also in English translation of the 4th German Ed., 2nd English Ed. (2 volumes) (1980), Pergamon Press, Oxford, 1205 pp.Google Scholar
Rimstidt, J. D. and Barnes, H. L. (1980) The kinetics of silica-water reactions. Geochim. Cosmochim. Ada, 44, 1683-99.CrossRefGoogle Scholar
Roedder, E. (1984) Fluid Inclusions. Reviews in Mineralogy, 12 (P. H. Ribbe, ed.) Mineralogical Society of America, 644 pp.CrossRefGoogle Scholar
Schieber, J. and Katsura, K. T. (1986) Sedimentation in epithermal veins of the Bohemia mining district, Oregon, U.S.A.: Interpretations and significance. Mineral. Deposita, 21, 322–8.Google Scholar
Thompson, J. B. Jr., (1959) Local equilibrium in metasomatic processes: p. 427-57 in Researches in Geochemistry (P. H. Abelson, ed.) John Wiley and Sons, New York.Google Scholar
Wiggins, L. B. and Craig, J. R. (1980) Reconnaissance of the Cu-Fe-Zn-S system: Sphalerite phase relationships. Econ. Geol., 75, 742-51.CrossRefGoogle Scholar