Abstract
The Ordovician Knox unconformity in the Appalachians developed in less than 10 m.y. during a time of initial collision of the passive margin and of eu- static sealevel lowering. It formed on cyclic limestones and dolomites of the 200- to 1200-m-thick Upper Knox-Beekmantown Group, and provides an example of the effects of long-term exposure on a carbonate shelf and the subsequent diagenesis related to karsting followed by deep burial. Erosional relief is over 100 m in the south. It increases over synclepositional structures and bevels down to Upper Cambrian rocks on the craton. The disconformity is virtually absent in the Pennsylvania depocenter.
Paleokarst features include paleotopographic highs, sinkholes and caves that extend to over 65 m below the unconformity, and intrastratal breccias down to 300 m. Near-vertical sinkholes are filled with carbonate breccia and gravels with fine dolomite matrix. Caves are filled with breccia and laminated dolomite. Intrastratal breccias up to 35 m thick and over 200 m long contain dolomite clasts commonly with fitted fabrics, in a fine dolomite matrix.
Nonluminescent calcite cements fill leached grains and intergranular spaces down to 200 m below the unconformity, and formed from slowly moving, oxidizing meteoric waters undergoing diffuse flow in an unconfined aquifer. Rapidly moving, conduit flow cave waters caused extensive dissolution of limestone beds locally forming intrastral breccias; some of these also may have resulted from dissolution in the mixing zone. During burial, compaction further fractured breccia beds, and in the Late Paleozoic, warm saline basinal brines (80°C to 200°C) caused further dissolution, dolomitization fronts surrounding breccia zones, and precipitation of saddle dolomite and associated sulfides, within permeable horizons.
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References
Anderson, G.M., 1983,Some geochemical aspects of sulphide precipitation in carbonate rocks, in Kis- varsanyi, G., Grant, S.K., Pratt, W.P., and Koenig, J.W., eds., Proceedings of the International Conference on Mississippi Valley-type Lead-Zinc Deposits: Univ. of Missouri-Rolla, MO, p. 61–76.
Back, W., and Hanshaw, B.B., 1970, Comparison of chemical hydrology of the carbonate peninsulas of Florida and Yucatan: Jour. Hydrology, v. 10, p. 330–368.
Back, W., Hanshaw, B.B., Pyle, T.E., Plummer, L.N., and Weidie, A.E., 1979, Geochemical significance of groundwater discharge and carbonate solution to the formation of Caleta Xel Ha, Quintana Roo, Mexico: Water Resources Research, v. 15, p. 1531–1535.
Bethke, C.M., 1986, Hydrologic constraints on the genesis of the Upper Mississippi Valley mineral district from Illinois basin brines: Econ. Geology, v. 81(2), p. 233–249.
Bird, J.M., and Dewey, J.F., 1970, Lithosphere plate- continental margin tectonics and the evolution of the Appalachian orogen: Geol. Soc. Amer. Bull., v. 81, p. 1031–1060.
Burst, J.F., 1969, Diagenesis of Gulf Coast clayey sediments and its possible relation to petroleum migration: Am. Assoc. Petroleum Geologists Bull., v. 53, p. 73–93.
Caless, J.R., 1983, Geology, paragenesis, and geochemistry of sphalerite mineralization at the Young Mine, Mascot-Jefferson City zinc district, east Tennessee: M.S. thesis, Virginia Polytechinic Institute and State University, Blacksburg, VA, 237 P.
Carothers, W.W., and Kharaka, Y.K., 1978, Aliphatic acid anions in oil-field waters—Implications for origin of natural gas: Amer. Assoc. Petroleum Geologists Bull., v. 62(12), p. 2441–2453.
Carothers, W.W., and Kharaka, Y.K., 1980, Stable carbon isotopes of HCO;$ in oil-field waters—Implications for the origin of C02: Geochim. Cos- mochim. Acta, v. 44, p. 323–332.
Carpenter, A.B., and Oglesby, T.W., 1976, A model for the formation of luminescently zoned calcite cements and its implications: Geol. Soc. America Abstracts with Programs, v. 8, p. 469–470.
Cathles, L.M., and Smith, A.T., 1983, Thermal constraints on the formation of Mississippi Valley-type lead—zinc deposits and their implications for episodic basin dewatering and deposit genesis: Econ. Geology, v. 78, p. 983–1002.
Chafetz, H.S., Wilkinson, B.H., and Love, K.M., 1985, Morphology and composition of nonmarine carbonate cements in near-surface settings, in Schneidermann, N., and Harris, P.M., eds., Carbonate cements: Soc. Econ. Paleontologists & Mineralogists Spec. Publ. 36, p. 337–369.
Champ, D.R., Gulens, J., and Jackson, R.E., 1979, Oxidation—reduction sequences in groundwater flow systems: Canadian Jour. Earth Sci., v. 16, p. 12–23.
Churnet, H.G., and Misra, K.C., 1981, Genetic implications of the trace element distribution pattern in the Upper Knox carbonate rocks, Copper Ridge district, east Tennessee: Sed. Geol., v. 30, p. 173–194.
Churnet, H.G., Misra, K.C., and Walker, K.R., 1982, Deposition and dolomitization of Upper Knox carbonate sediments, Copper Ridge district, east Tennessee: Geol. Soc. America Bull., v. 93, p. 76–86.
Collins, J.A., and Smith, L., 1975, Zinc deposits related to diagenesis and intrakarstic sedimentation in the Lower Ordovician St. George Formation, western Newfoundland: Bull. Canadian Petroleum Geologists, v. 23, p. 393–427.
Colton, G.W., 1970, The Appalachian Basin—its depositional sequence and their geologic relationships, in Fisher, G.W., et al., eds., Studies of Appalachian geology-central and southern: New York, Interscience, p. 5–47.
Crawford, M.L., 1981, Phase equilibria in aqueous fluid inclusions, in Hollister, L.S., and Crawford, M.L., eds., Short course in fluid inclusions-applications to petrology: Mineralogical Assoc. Canada Short Course Handbook, 6, p. 75–100.
Dickson, J.A.D., 1965, A modified staining technique for carbonates in thin section: Nature, v. 205, p. 587.
Dorobek, S.L., 1984, Stratigraphy, sedimentology, and diagenetic history of the Siluro-Devonian Helderberg Group, central Appalachians: M.S. thesis, Virginia Polytechnic Institute and State University, Blacksburg, VA, 237 p.
Dorobek, S.L., 1987, Petrography, geochemistry, and origin of burial diagenetic facies, Siluro-Devon- ian Helderberg Group (carbonate rocks), Central Appalachians; A.A.P.G. Bull., v. 7(5), p. 492–514.
Ebers, M.L., and Kopp, O.C., 1979, Cathodolu- minescent microstratigraphy in gangue dolomite, the Jefferson City district, Tennessee: Econ. Geology, v. 74, p. 908–918.
Fiichtbauer, H., and Hardie, L.A., 1976, Experimentally determined homogeneous distribution coefficients for precipitated magnesian calcites— application to marine carbonate cements: Geol. Soc. America Abstracts with Programs, v. 8, p. 887.
Gorody, A.W., 1980, The Lower Ordovician Mascot Formation, Upper Knox Group, in north central Tennessee, Part I: Paleoenvironmental history; Part II: Dolomitization and paleohydraulic history: Ph.D. thesis, Rice University, Houston, TX, 181 P-.
Grover, G., Jr., and Read, J.F., 1983, Paleoaquifer and deep burial related cements defined by cath- odoluminescent patterns, Middle Ordovician carbonates, Virginia: Amer. Assoc. Petrologists Bull, v. 7(8), p. 1275–1303.
Harris, L.D., 1969, Kingsport Formation and Mascot Dolomite (Lower Ordovician) of east Tennessee: Tennessee Division of Geology Report of Investigations 23, 139 p.
Harris, L.D., 1971, A Lower Paleozoic paleoaquifer—the Kingsport Formation and Mascot Dolomite of Tennessee and southwest Virginia: Econ. Geology, v. 66, p. 735–743.
Hatcher, R.D., Jr., 1972, Developmental model for the southern Appalachians: Geol. Soc. America Bull., v. 83, p. 2735–2760.
Hitchon, B., 1969, Fluid flow in the Western Canada sedimentary basin, 1. Effect of topography: Water Resources Research, v. 5(1), p. 186–195.
Hoagland, A.D., Hill, W.T., and Fulweiler, R.E., 1965, Genesis of the Ordovician zinc deposits in east Tennessee: Econ. Geology, v. 60, p. 693–714.
Ichikuni, M., 1983, Anionic substitution in calcium carbonate, in Augustithis, S.S., ed., The significance of trace elements in solving petrographic problems and controversies: Athens, Greece, Theophrastus Publications, S.A., p. 81–94.
Jacobi, R.D., 1981, Peripheral bulge—a causal mechanism for the Lower/Middle Ordovician unconformity along the western margin of the Northern Appalachians: Earth and Planetary Sci. Letters, v. 56, p. 245–251.
James, N.P., and Choquette, P.W., 1984, Diagenesis 9-limestones-the meteoric diagenetic environment: Geosci. Canada, v. 11(4), p. 161–194.
Johns, W.D., and Shimoyama, A., 1972, Clay minerals and petroleum-forming reactions during burial and diagenesis: Amer. Assoc. Petroleum Geologists Bull., v. 56, p. 2160–2167.
Kharaka, Y.K., Carothers, W.W., and Rosenbauer, R.J., 1983, Thermal decarboxylation of acetic acid—implications for origin of natural gas: Geo- chim. Cosmochim. Acta, v. 47, p. 397–402.
Kyle, J.R., 1976, Brecciation, alteration and mineralization in the central Tennessee zinc district: Econ. Geology, v. 71, p. 892–903.
Kyle, J.R., 1983, Economic aspects of subaerial carbonates, in Scholle, P.A., Bebout, D.G., and Moore, C.L., eds., Carbonate depositional environments: Amer. Assoc. Petroleum Geologists, Tulsa, OK, p. 73–92.
McCormick, J.E., and Rasnick, F.D., 1983, Mine geology of ASARCO’s Young mine, in Tennessee zinc deposits field trip guide book, March 9–11, 1983: Virginia Tech Dept. Geol. Sci. Guide Book No. 9, p. 39–44.
Meyers, W.J., 1978, Carbonate cements: their regional distribution and interpretation in Missis- sippian limestones of southwestern New Mexico: Sedimentology, v. 25, p. 371–400.
Misra, K.C., Churnet, H.G., and Walker, K.R., 1983, Carbonate-hosted zinc deposits of east Tennessee, in Tennessee zinc deposits field trip guide book, March 9–11, 1983: Virginia Tech Dept. Geol. Sci. Guide Book No. 9, p. 2–20.
Montanez, LP. (in prep.), Diagenesis and dolomitization of Upper Knox carbonates, southern Appalachians: Ph.D. thesis, Virginia Polytechnic Institute and State University, Blacksburg, VA.
Mussman, W.J., and Read, J.F., 1986, Sedimentology and development of a passive- to convergent- margin unconformity—Middle Ordovician Knox unconformity, Virginia Appalachians: Geol. Soc. America Bull., v. 97, p. 282–295.
Niemann, J.C., 1984, Regional cementation associated with unconformity-sourced aquifers and burial fluids, Mississippian Newman Limestone, Kentucky: M.S. thesis, Virginia Polytechnic Institute and State University, Blacksburg, VA, 200 p.
Perry, E.A., and Hower, J., 1970, Burial diagenesis in Gulf Coast pelitic sediments: Clays and Clay Minerals, v. 18, p. 165–177.
Plummer, L.N., 1975, Mixing of seawater with calcium carbonate groundwater: Geol. Soc. America Memoir, v. 142, p. 219–236.
Quinlan, G.M., and Beaumont, C., 1984, Appalachian thrusting, lithospheric flexure, and the Paleozoic stratigraphy of the eastern interior of North America: Canadian Jour. Earth Sci., v. 21, p. 973–996.
Quinlan, J.F., 1972, Karst-related mineral deposits and possible criteria for the recognition of paleo- karsts—a review of preservable characteristics of Holocene and older karst terranes: 24th Internat. Geological Congress, v. 6, p. 156–167.
Read, J.F., 1980, Carbonate ramp-to-basin transitions and foreland basin evolution, Middle Ordovician, Virginia Appalachians: Amer. Assoc. Petroleum Geologists Bull., v. 64, p. 1575–1612.
Read, J.F., (in press), Evolution of Cambro-Ordo- vician passive margin, U.S. Appalachians: Decade of North American Geological Synthesis, Appa- lachians-Ouachitas Volume, Geological Society of America.
Read, J.F., and Grover, G.A., Jr., 1977, Scalloped and planar erosion surfaces, Middle Ordovician limestones, Virginia—analogues of Holocene exposed karst or tidal rock platforms: Jour. Sed. Petrology, v. 47, p. 956–972.
Reinhardt, J., and Hardie, L.A., 1976, Selected examples of carbonate sedimentation, lower Paleozoic of Maryland: Maryland Geol. Survey Guidebook 5, 53 p.
Rodgers, J., 1968, The eastern edge of the North American continent during the Cambrian and Early Ordovician, in Zen, E-an, et al., eds., Studies of Appalachian geology-northern and maritime: New York, Interscience, p. 141–149.
Roedder, E., 1971, Fluid inclusion evidence on the environment of formation of mineral deposits of the southern Appalachian Valley: Econ. Geology, v. 6, p. 777–791.
Rosenberg, P.E., and Holland, H.D., 1964, Calcite- dolomite-magnesite stability relations in solutions at elevated temperatures: Science, v. 145, p. 700–701.
Ross, R.J., Jr, et al., 1982, The Ordovician system in the United States, correlation chart and explanatory notes: International Union of Geological Sciences, Publ. No. 12, 73 p.
Shanmugam, G., and Walker, K.R., 1980, Sedimentation, subsidence, and evolution of a foredeep basin in the Middle Ordovician, southern Appalachians: Amer. Jour. Science, v. 280, p. 479–496.
Slaymaker, S.L., and Watkins, J.S., 1978, A plate tectonics model of the southern Appalachians suggested by gravity data (abstr.): Geol. Soc. America Abstracts with Programs, v. 10, p. 198.
Sloss, L.L., 1963, Sequences in the cratonic interior of North America, Geol. Soc. America Bull., v. 74, p. 93–114.
Suter, D.R., and Tillman, C.G., 1973, The conodont genus Multioistodus from supratidal limestones in the Beekmantown Formation of the Appalachians of west-central Virginia (abstr.): Geol. Soc. America Abstracts with Programs, v. 5(5), p. 441–442.
Sweeting, M.M., 1972, Karst landforms: London, MacMillan, 362 p.
Taylor, M., Kelly, W.C., Kessler, S.E., McCormick, J.E., Rasnick, F.D., and Mellon, M.V., 1983a, Relationship of zinc mineralization in east Tennessee to Appalachian orogenic events: in Kisvarsanyi, G., Grant, S.K., Pratt, W.P., and Koenig, J.W., eds., Proceedings of the International Conference on Mississippi Valley-type Lead-Zinc Deposits: Univ. of Missouri—Rolla, MO. p. 271–278.
Taylor, M., Kessler, S.E., Cloke, P.L., and Kelly, W.C., 1983b, Fluid inclusion evidence for fluid mixing, Mascot—Jefferson City zinc district, Tennessee: Econ. Geology, v. 78(7), p. 1425–1439.
Thrailkill, J., 1968, Chemical and hydrologic factors in the excavation of limestone caves: Geol. Soc. America Bull., v. 79, p. 19–46.
Tillman, C.G., 1976, A Prioniodus apparatus from beds of Whiterock age (Ordovician), Harrisonburg, Virginia (abstr.): Geol. Soc. America Abstracts with Programs, v. 8(4), p. 513.
Waples, D.W., 1980, Time and temperature in petroleum formations-application of Lopatin’s method to petroleum exploration: Amer. Assoc. Petroleum Geologists Bull., v. 64, p. 916–926.
Webb, F., Jr., 1959, Geology of the Middle Ordovician limestones in the Rich Valley area, Smyth County, Virginia: M.S. thesis, Virginia Polytechnic and State University, Blacksburg, VA, 96 p.
White, W.B., 1969, Conceptual models for carbonate aquifers: Groundwater, v. 7, p. 15–21.
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Mussman, W.J., Montanez, I.P., Read, J.F. (1988). Ordovician Knox Paleokarst Unconformity, Appalachians. In: James, N.P., Choquette, P.W. (eds) Paleokarst. Springer, New York, NY. https://doi.org/10.1007/978-1-4612-3748-8_11
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