RI0145D
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RI0145D. Origin of Silver-Copper-Lead Deposits in Red-Bed Sequences of Trans-Pecos Texas: Tertiary Mineralization in Precambrian, Permian, and Cretaceous Sandstones, by J. G. Price, C. D. Henry, A. R. Standen, and J. S. Posey. 65 p., 37 figs., 15 tables, 1 appendix, 1985. doi.org/10.23867/RI0145D. Downloadable PDF.
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ABSTRACT
Silver deposits occur in Precambrian, Permian, and Cretaceous red-bed sequences near Van Horn, Texas. These deposits are geochemically similar and contain economically important quantities of silver, copper, and lead, as well as anomalously high amounts of arsenic, zinc, cadmium, and molybdenum. Gold is not enriched. Primary minerals include chalcopyrite, tennantite-tetrahedrite, bornite, galena, sphalerite, acanthite, pyrite, marcasite, barite, and calcite.
The deposits are dominantly steeply dipping veins. Strata-bound occurrences are near veins or closely spaced fractures. Structural evidence, including orientations of veins, relative ages of fractures, and relationships to major tectonic events in the region, suggests that the most likely time of mineralization was during late Basin and Range extensional deformation. Ore deposition probably occurred at least 18 m.y. after the period of voluminous silicic volcanism (38 to 28 m.y.a.) in the Trans-Pecos region.
Other features indicate that, in contradiction to a hypothesis suggested by previous workers, the deposits did not form as a result of middle Tertiary magmatism. (1) Centers of igneous activity were distant from the sites of mineralization. (2) Potentially reactive limestones above and below the ore zones in red beds are generally unmineralized. (3) Zones of argillic, phyllic, and propylitic alteration typical of igneous-hydrothermal veins are absent. (4) Characteristic igneous hydrothermal gangue minerals such as quartz and fluorite are rare or absent. (5) Homogenization temperatures of fluid inclusions in barite and calcite suggest formation temperatures in the range of 120°C to 170°C, that is, lower than temperatures typical in copper-lead-zinc-bearing igneous-hydrothermal veins. These temperatures are higher than those usually attributed to strata-bound, red-bed copper deposits. The elevated formation temperatures are the result of high heat flow in the Basin and Range province of Texas at the time of mineralization; they are not the result of igneous activity.
The hypothesis developed in this study on the origin of the veins involves a rise of moderate-temperature, moderately saline hydrothermal fluids along Basin and Range fractures and precipitation of metal sulfides in response to mixing with shallow ground water. This hypothesis has implications for exploration of additional deposits in Trans-Pecos Texas and elsewhere.
Keywords: Texas, Trans-Pecos, economic geology, metals, silver, copper, lead, red beds
CONTENTS
ABSTRACT
INTRODUCTION
Purpose of study
Scope of study
Previous work
History of mining
Methods of investigation
REGIONAL GEOLOGY
Stratigraphy
Precambrian rocks
Paleozoic rocks
Mesozoic rocks
Cenozoic rocks
Limited lithologic control of mineralizationand tectonics
Precambrian deformation
Paleozoic deformation
Mesozoic· Cenozoic activity
Laramide deformation
Middle Tertiary magmatism
Basin and Range extension
STRUCTURAL CONTROLS OF VEIN MINERALIZATION
East-northeast and northeast veins in Precambrian rocks
East-northeast and northeast veins in Cretaceous rocks
Structures in Permian host rocks
Changing stress orientations with time and probable age of vein mineralization
Other mineralization along Basin and Range faults
MINERALOGY AND GEOCHEMISTRY OF ORES AND HOST ROCKS
Primary ore minerals
Secondary minerals
Gangue minerals
Wall-rock alteration
Geochemical character of the ores
Comparison with igneous-hydrothermal ores
Comparison with other ores in red beds
Fluid-inclusion studies
Samples
Data from heating
Data from freezing
Comparison with other areas of known hydrothermal activity associated with Basin and Range faulting
Carbon and sulfur isotope studies
ORIGIN OF DEPOSITS
Review of observations and conclusions
Unanswered questions
EXPLORATION POTENTIAL
ACKNOWLEDGMENTS
REFERENCES
APPENDIX: STRUCTURAL AND CHEMICAL DATA
Figures
1. Locations of silver-copper-lead deposits in sandstones near Van Horn, Texas
2. Geology and locations of silver-copper-lead deposits in Precambrian rocks of the Van Horn - Allamoore district
3. Glory hole east of the East shaft, Hazel mine
4. Stratiform ore at the Sancho Panza mine
5. Nearly vertical vein cutting Cretaceous Yucca Formation conglomerate at the Rossman prospect, Indio Mountains
6. Headframe at the East shaft, Hazel mine
7. Simplified geologic map of the Plata Verde mine, Trans-Pecos Texas
8. Geologic map of the central Indio Mountains
9. Stratigraphic column, Van Horn area
10. Yucca Formation, 'Central Indio Mountains
11. Eastward-dipping Cretaceous sedimentary rocks east of the Indio Fault, Indio Mountains
12. Cross section A-A', illustrating major structural features in the Indio Mountains
13. Orientations of faults, slickenlines, and corresponding principal stress axes, Laramide deformation, Indio Mountains
14. Strike rosettes of veins and dikes that were emplaced during the major period of igneous activity, 32 to 41 m.y.a., in the Trans-Pecos region
15. Strike rosettes of early Miocene Rim Rock dikes
16. Orientations of faults and slickenlines, Basin and Range deformation, Indio Mountains
17. Veins at the Hazel mine in 1891
18. Orientations of mineralized fractures at the Mohawk mine.
19. Calcite-filled fractures in a streambed at the Hazel mine
20. Typical fracture intersections in the Hazel Formation
21. Orientations of fractures at mines in the Hazel Formation and at nearby exposures in the Hueco Formation
22. Fracture patterns at and near silver-copper-lead deposits in the Precambrian Hazel Formation and the Cretaceous Yucca Formation
23. Proposed orientations of stress during Late Cretaceous through Recent(?) time, Trans-Pecos Texas
24. Open cut of manganese-barite vein along a Basin and Range normal fault at the Mayfield prospect
25. Photomicrograph of Hazel ore from glory hole, East shaft area
26. Photomicrograph of sample collected from the dump at the Pecos mine
27. Photomicrograph of clusters of radiating hemimorphite blades, Purple Sage mine, Indio Mountains
28. Photomicrograph of quartz overgrowths, Finlay prospect, Indio Mountains
29. Photomicrographs of gray, weakly altered sandstone, Pecos mine
30. Photomicrograph of disseminated copper mineralization at the Rossman prospect, Indio Mountains
31. Geochemical characteristics of ores and unmineralized rocks in the Precambrian Hazel Formation
32. Geochemical characteristics of Plata Verde ores and unmineralized rocks in the Powwow Member of the Permian Hueco Limestone
33. Geochemical characteristics of mineralized and unmineralized rocks in the Cretaceous Yucca Formation
34. Two-phase (liquid-vapor) fluid inclusion in barite, Pecos mine
35. Homogenization temperatures of fluid inclusions from the Pecos mine in the Precambrian Hazel Formation and from the Finlay prospect in the Cretaceous Yucca Formation
36. Freezing temperatures of fluid inclusions from the Pecos mine in the Precambrian Hazel Formation and from the Finlay prospectin the Cretaceous Yucca Formation
37. Homogenization temperatures of fluid inclusions from the Mayfield manganese prospect
Tables
1. Estimated total production, silver grade, copper-to-silver ratio, and silver-to-gold ratio of silver-copper-lead deposits in red-bed sequences in Trans-Pecos Texas
2. Estimated ore, copper, and silver production from mines in the Van Horn - Allamoore district
3. Average copper grade, silver grade, and copper-to-silver ratio, based on production records from the Van Horn - Allamoore district
4. Tectonic history of the Van Horn area, Trans-Pecos Texas
5. Slickenline data that correspond to only one of four probable phases of deformation, Indio Mountains
6. Percentages of fractures of the four major trends in the Hazel Formation that exhibit extensional features
7. Relative ages of fractures determined from fracture intersections in the Hazel Formation
8. Vein mineralogy, Precambrian Hazel Formation, Van Horn area
9. Ore mineralogy, Powwow Member of the Permian Hueco Limestone, Plata Verde mine
10. Mineralogy, hosts, and controls on silver-copper-lead deposits, Cretaceous Yucca Formation, Indio Mountains
11. X-ray powder diffraction data on a sulfur-rich beudantite-group mineral, Finlay prospect, Indio Mountains
12. Electron-microprobe analysis of a sulfur-rich beudantite-group mineral, Finlay prospect, Indio Mountains
13. Silver grades and silver-to-gold ratios in middle Tertiary, igneous hydrothermal ores in the Trans-Pecos region
14. Carbon isotope data from the Eureka prospect and Precambrian carbonates
15. Sulfur isotope data on vein barite, Van Horn area
Appendix Tables
A1. Minor fault orientations in the Indio Mountains
B1. Geochemical data on ores in the Hazel Formation
B2. Geochemical data on weakly mineralized sandstone and siltstone wall rock of the Hazel Formation
B3. Geochemical data on unmineralized sandstone and siltstone of the Hazel Formation
B4. Geochemical data on other types of copper ore from the Hazel and Allamoore Formations
B5. Geochemical data on mineralized Yucca sandstones and conglomerates, Indio Mountains
B6. Geochemical data on weakly mineralized Yucca sandstones, Indio Mountains
B7. Geochemical data on unmineralized Yucca sandstones, Indio Mountains, and on average sandstone
B8. Geochemical data on limestone and calcite in the Yucca Formation, Indio Mountains
Citation
Price, J. G., Henry, C. D., Standen, A. R., and Posey, J. S., 1985, Origin of Silver-Copper-Lead Deposits in Red-Bed Sequences of Trans-Pecos Texas: Tertiary Mineralization in Precambrian, Permian, and Cretaceous Sandstones: The University of Texas at Austin, Bureau of Economic Geology, Report of Investigations No. 145, 65 p.