Abstract
The Upper Ordovician (Sandbian; late Whiterockian to Mohawkian) Bromide Formation of south-central Oklahoma was deposited along a distally steepened ramp that descended into the Southern Oklahoma Aulacogen (SOA). It provides an unparalleled opportunity to examine a spectrum of marine facies that extended from back ramp peritidal settings to the center of the basin. The depositional history and environmental context of the unit are reconsidered using lithofacies analysis and the characterization of sequence stratigraphic patterns at a variety of hierarchical scales. Inner-ramp (above fair weather wavebase; FWWB) lithofacies suggest deposition in a range of environments: tidal flat, lagoon, shoreface, semi-restricted shallow subtidal, and bioclastic shoal. Middle-ramp environments between FWWB and storm wavebase (SWB) are thick and faunally diverse, and consist of rhythmically bedded marls, wackestone, packstone, and shales. Outer-ramp environments (below SWB) are represented by either fissile tan-green shale or thin-bedded carbonate mudstone and shale. Ramp stratigraphy, facies associations, and bounding surfaces suggest that three third-order depositional sequences are present in the Bromide. They demonstrate the transition from a clastic-dominated ramp in the late Whiterockian to a carbonate-dominated ramp in the Mohawkian, and show that the deposition of the Bromide was considerably more complex than the simple transgressive–regressive cycle traditionally used to describe accommodation dynamics in the basin. Meter and decameter-scale cycles (high-frequency sequences) are a common motif within the depositional sequences, and the Corbin Ranch Submember records an important peritidal succession prior to a major sequence boundary with the overlying Viola Springs Formation. New correlations based on measured sections, outcrop gamma-ray profiles, and subsurface well-logs document a novel pattern where the middle Bromide depositional sequence 2 (Mountain Lake Member) expanded down-ramp, whereas the succeeding carbonate-dominated sequence 3 (Pooleville Member) was progressively removed down-ramp. This demonstrates the existence of a major, regionally angular unconformity at the base of the Viola Springs Formation that has implications for basin evolution. Other implications include the validation of high-frequency sequences as a model for elementary cycles in mixed carbonate-siliciclastic systems and, more regionally, documentation of a new depositional sequence at the Turinian–Chatfieldian stage boundary.
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References
Amsden TW, Sweet WC (1983) Upper Bromide Formation and Viola Springs Group (Middle and Upper Ordovician) in eastern Oklahoma. Okla Geol Surv Bull 132:1–76
Arnott RWC (1995) The parasequence definition—are transgressive deposits inadequately addressed? J Sediment Res B65:1–6
Baird GC, Brett CE (1986) Erosion on an anaerobic seafloor: significance of reworked pyrite deposits from the Devonian of New York State. Palaeogeography, Palaeoclimatology, Palaeoecology 57:157–193
Bambach RK, Scotese CR, Ziegler AM (1980) Before Pangea: the geographies of the Paleozoic world. Am Sci 68:26–38
Bauer JA (1994) Conodonts from the Bromide Formation (Middle Ordovician), south-central Oklahoma. J Paleontol 68(2):358–376
Baum GR, Vail PR (1988) Sequence stratigraphic concepts applied to Paleogene outcrops, Gulf and Atlantic basins. In: Wilgus CK, Hastings BK, Posamentier H, Wagoner JV, Ross CA, Kendall CGSC (eds) Sea-level changes: an integrated approach, vol 42. Society of Economic Paleontology and Mineralogy Special Publication, pp 309–327
Bergström SM, Xu C, Gutierrez-Marco JC, Dronov A (2008) The new chronostratigraphic classification of the Ordovician system and its relation to major regional series and stages and to ∂13C chemostratigraphy. Lethaia 42:97–107
Bergström SM, Young S, Schmitz B (2010) Katian (Upper Ordovician) ∂13C chemostratigraphy and sequence stratigraphy in the United States and Baltoscandia: a regional comparison. Palaeogeography, Palaeoclimatology, Palaeoecology 296:217–234
Boyd R (2010) Transgressive wave-dominated coasts. In: James NP, Dalrymple RW (eds) Facies models, vol 4. Geological Society of Canada, pp 265–294
Brett CE, Algeo TJ (2001) Sequence stratigraphy of Upper Ordovician and Lower Silurian strata of the Cincinnati Arch region. In: Algeo TJ, Brett CE (eds) Sequence, cycle and event stratigraphy of the Upper Ordovician and Silurian Strata of the Cincinnati Arch Region. Kentucky Geological Survey Field Trip Guidebook 1, series XII. SEPM, Cincinnati OH
Brett CE, McLaughlin PI, Baird GC, Cornell SR (2004) Comparative sequence stratigraphy of the Upper Ordovician (Turinian–Edenian) of the Trenton shelf (New York–Ontario) and Lexington Platform (Kentucky, southern Ohio) successions: implications for improved paleogeographic resolution of eastern Laurentia. Palaeogeography, Palaeoclimatology, Palaeoecology 210:295–329
Brett CE, Algeo TJ, McLaughlin PI (2008) Use of event beds and sedimentary cycles in high-resolution stratigraphic correlation of lithologically repetitive successions: the upper Ordovician Kope Formation of northern Kentucky and southern Ohio. In: Harries PJ (ed) High-resolution approaches in stratigraphic paleontology. Springer, Berlin Heidelberg New York, pp 315-350
Brett CE, Zambito JJ, Hunda BR, Schindler E (2012) Mid-Paleozoic trilobite Lagerstätten: models of diagenetically enhanced obrution horizons. Palaios 27:326–345
Candelaria MP, Handford CR (1995) Sequence stratigraphic model for Simpson Group of the southern midcontinent. In: Hyne NJ (ed) Sequence stratigraphy of the midcontinent, vol 4. Tulsa Geological Society Special Publication, pp 319–348
Carlucci JR, Westrop S, Amati L (2010) Tetralichine trilobites from the Upper Ordovician of Oklahoma and Virginia, and phylogenetic systematics of the Tetralichini. J Paleontol 84:1099–1120
Carlucci JR, Westrop SR, Amati L, Adrain JM, Swisher RE (2012) A Systematic revision of the Upper Ordovician trilobite genus Bumastoides (Trilobita: Illaenidae) with new species from Oklahoma, Virginia, and Missouri. J Syst Palaeontol 10:679–723
Catuneanu O, Abreu V, Bhattacharya JP, Blum MD, Dalrymple RW, Eriksson PG, Fielding CR, Fisher WL, Galloway WE, Giblingi MR, Giles KA, Holbrook JM, Jordan R, Kendall CGSC, Macurda B, Martinsen OJ, Miall AD, Neal JE, Nummedal D, Pomar L, Posamentier HW, Pratt BR, Sarg JF, Shanley KW, Steel RJ, Strasser A, Tucker ME, Winker C (2009) Towards the standardization of sequence stratigraphy. Earth Sci Rev 92:1–33
Cooper GA (1956) Early middle Ordovician of the United States. In: Bassett MG (ed) The Ordovician system. University of Wales Press and National Museum of Wales, pp 171–194
Derby JR, Bauer JA, Creath WB, Dresbach RI, Ethington RL, Loch JD, Stitt JH, McHargue TR, Miller JF, Miller MA, Repetski JE, Sweet WC, Taylor JF, Williams M (1991) Biostratigraphy of the Timbered Hills, Arbuckle, and Simpson groups, Cambrian and Ordovician, Oklahoma: a review of correlation tools and techniques available to the explorationist. Okla Geol Surv Circ 92:15–41
Embry AF, Johannessen EP (1992) T–R sequence stratigraphy, facies analysis and reservoir distribution in the uppermost Triassic-lower Jurassic succession, western Sverdrup Basin, arctic Canada. In: Vorren TO, Bergsager E, Dahl-Stamnes OA et al (eds) Arctic geology and petroleum potential, vol 2. Norwegian Petroleum Society Special Publication, pp 121–146
Ettensohn FR, Fulton LP, Kepferle RC (1979) Use of scintillometer and gamma-ray logs for correlation and stratigraphy in homogeneous black shales: summary. Geol Soc Am Bull 90:421–423
Fay RO, Graffham AA (1982) Stratigraphic studies. In: Sprinkle J (ed) Echinoderm Faunas from the Bromide Formation (Middle Ordovician) of Oklahoma, vol 1. Univ Kans Paleontol Contrib, Monograph, pp 195–209
Fay RO, Graffham AA, Sprinkle J (1982a) Previous studies of Bromide echinoderms. In: Sprinkle J (ed) Echinoderm Faunas from the Bromide Formation (Middle Ordovician) of Oklahoma, vol 1. Univ Kans Paleontol Contrib, Monograph, pp 35–43
Fay RO, Graffham AA, Sprinkle J (1982b) Appendix: measured sections and collecting localities. In: Sprinkle J (ed) Echinoderm faunas from the Bromide Formation (Middle Ordovician) of Oklahoma. University of Kansas Paleontological Contributions Monograph, pp 335–369
Finney SC (1986) Graptolite biofacies and correlation of eustatic, subsidence, and tectonic events in the Middle to Upper Ordovician of North America. PALAIOS 1:435–461
Finney S (2005) Global series and stages for the Ordovician system: a progress report. Geol Acta 3:309–316
Grimwood JL, Coniglio M, Armstrong DK (1999) Blackriveran carbonates from the subsurface of the Lake Simcoe area, southern Ontario; stratigraphy and sedimentology of a low energy carbonate ramp. Can J Earth Sci 36:871–890
Ham WE (1969) Regional geology of the Arbuckle Mountains, Oklahoma. Oklahoma Geological Survey Guide Book 17, 52 p
Handford CR, Loucks RG (1993) Carbonate depositional sequences and systems tracts—response of carbonate platforms to relative sea-level changes. In: Loucks RG, Sarg JF (eds) Carbonate sequence stratigraphy: Recent developments and applications, vol 57. American Association of Petroleum Geologists Memoir, pp 3–41
Harris RW (1957) Ostracoda of the Simpson Group. Okla Geol Surv Bull 75:1–333
Holland SM, Patzkowsky ME (1996) Sequence stratigraphy and long-term paleo-oceanographic changes in the Middle and Upper Ordovician of the eastern United States. In: Witzke B, Ludvigson G, Day J (eds) Paleozoic sequence stratigraphy: views from the North American Craton, GSA special paper 306. Geol Soc Am, Boulder CO, pp 117–129
Holland SM, Patzkowsky ME (1997) Distal orogenic effects on peripheral bulge sedimentation: middle and upper Ordovician of the Nashville Dome. J Sediment Res 67:250–263
Holland SM, Miller AI, Dattilo BF, Meyer DL, Diekmeyer SL (1997) Cycle anatomy and variability in the storm-dominated type Cincinnatian (Upper Ordovician): coming to grips with cycle delineation and genesis. J Geol 105:135–152
Holland SM (2008) Climate-driven storm cyclicity. In: McLaughlin PI, Brett CE, Holland SM, Storrs GW (eds) Stratigraphic renaissance in the Cincinnati Arch, vol 2. Cincinnati Museum Center Scientific Contributions, pp 44–57
Hunt D, Tucker ME (1992) Stranded parasequences and the forced regressive wedge systems tract: deposition during base-level fall. Sediment Geol 81:1–9
Hunt D, Tucker ME (1995) Stranded parasequences and the forced regressive wedge systems tract: deposition during base-level fall-reply. Sediment Geol 95:147–160
James NP, Kendall AC, Pufahl PK (2010) Introduction to biological and chemical sedimentary facies models. In: James NP, Dalrymple RW (eds) Facies models, vol 4. Geological Society of Canada, pp 323–340
Jennette DC (1986) Storm dominated cyclic ramp deposits of the Kope-Fairview transition (Upper Ordovician), southwestern Ohio and northern Kentucky. Unpublished MS Thesis, University of Cincinnati 210 pp
Johnson KS, Amsden TW, Denison RE, Dutton SP, Goldstein AG, Rascoe B, Sutherland PK, Thompson DM (1988) Southern midcontinent region. In: Sloss LL (ed) Sedimentary cover—North American craton, U.S. Geological Society of America, vol D-2. The Geology of North America, pp 307–359
Johnson K (1991) Geologic overview and economic importance of late Cambrian and Ordovician rocks in Oklahoma. In: Johnson K (ed) Late Cambrian–Ordovician Geology of the Southern Midcontinent 1989 Symposium. Oklahoma Geological Survey Circular 92, Norman, pp 3–14
Johnson JG, Murphy MA (1984) Time-rock model for Siluro-Devonian continental shelf, western United States. Geol Soc Am Bull 95:1349–1359
Johnson JG, Klapper G, Sandberg CA (1985) Devonian eustatic fluctuations in Euramerica. Geol Soc Am Bull 96:567–587
Jones B (2010) Warm-water neritic carbonates. In: James NP, Dalrymple RW (eds) Facies Models, vol 4. Geological Association of Canada, pp 341–370
Karim T, Westrop S (2002) Taphonomy and paleoecology of Ordovician Trilobite clusters, Bromide Formation, south-central Oklahoma. PALAIOS 17:394–403
Longman MW (1976) Depositional history, paleoecology, and diagenesis of the Bromide Formation (Ordovician) Arbuckle Mountains. University of Texas at Austin, Oklahoma 311 pp
Longman MW (1982a) Depositional environments. In: Sprinkle J (ed) Echinoderm Faunas from the Bromide Formation (Middle Ordovician) of Oklahoma, vol 1. University of Kansas Paleontological Contributions, Monograph, pp 17–29
Longman MW (1982b) Depositional setting and regional characteristics. In: Sprinkle J (ed) Echinoderm Faunas from the Bromide Formation (Middle Ordovician) of Oklahoma. The University of Kansas Paleontological Contributions, vol 1. Monograph, pp 6–10
McLaughlin P, Brett C, Taha-McLaughlin S, Cornell S (2004) High-resolution sequence stratigraphy of a mixed carbonate-siliciclastic cratonic ramp (Upper Ordovician; Kentucky–Ohio, USA): insights into the relative influence of eustasy and tectonics through analysis of facies gradients. Palaeogeography, Palaeoclimatology, Palaeoecology 210:267–294
McLaughlin PI, Brett C, Wilson M (2008) Hierarchy of sedimentary discontinuity surfaces and condensed beds from the Middle Paleozoic of Eastern North America: implications for cratonic sequence stratigraphy. In: Pratt B, Holmden C (eds) Dynamics of epeiric seas, vol 48. Geological Association of Canada special paper, pp 175–200
McPherson JG, Denison RE, Kirkland DW, Summers DM (1988) Basal sandstone of the Oil Creek Formation in the quarry of the Pennsylvania Glass Sand Corporation, Johnson County, Oklahoma. In: Hayward OT (ed) Centennial Field Guide 4. Geological Society of America, South Central Section, pp 165–170
Plint AG (1991) High-frequency relative sea-level oscillations in the Upper Cretaceous shelf clastics of the Alberta Foreland Basin: evidence for a Milankovitch-scale galcio-eustatic control? In: Macdonald DIM (ed) Sedimentation, Tectonics and Eustasy: International Association of Sedimentologists, Special Publication 12. Blackwell Science, Oxford, pp 409–428
Plint AG, Nummedal D (2000) The falling stage systems tract: recognition and importance in sequence stratigraphic analysis. In: Hunt D, Gawthorpe RL (eds) Sedimentary response to forced regression, vol 172. Geological Society of London Special Publication, pp 1–17
Pomar L, Morsilli M, Hallock P, Badenas B (2012) Internal waves, an under-explored source of turbulence events in the sedimentary record. Earth Sci Rev 111:56–82
Pope M, Read JF (1997) High-resolution surface and subsurface sequence stratigraphy of Late Middle to Late Ordovician (Late Mohawkian-Cincinnatian) foreland basin rocks, Kentucky and Virginia. AAPG Bull 81:1866–1893
Posamentier HW, Vail PR (1988) Eustatic controls on clastic deposition II—sequence and systems tracts models. In: Wilgus CK, Hastings BS, Kendall CGSC, Posamentier HW, Ross CA, Wagoner JCV (eds) Sea level changes—an integrated approach. Special Publication, vol 42. Society of Economic Paleontologists and Mineralogists, pp 125–154
Posamentier HW, Morris WR (2000) Aspects of the stratal architecture of forced regressive deposits. In: Hunt D, Gawthorpe RL (eds) Sedimentary responses to forced regressions, vol 172. Geological Society of London Special Publication, pp 19–46
Read JF (1980) Carbonate ramp-to-basin transitions and foreland basin evolution, Middle Ordovician, Virginia Appalachians. AAPG Bull 64:1575–1612
Rosenau NA, Herrmann AD, Leslie SA (2012) Conodont apatite ∂180 values from a platform margin setting, Oklahoma, USA: implications for initiation of late Ordovician icehouse conditions. Palaeogeography, Palaeoclimatology, Palaeoecology 315–316:172–180
Salvador A (1994) International stratigraphic guide: a guide to stratigraphic classification, terminology, and procedure. Geological Society of America, Boulder
Shaw F (1974) Simpson Group (Middle Ordovician) Trilobites of Oklahoma. J Paleontol Memoir 48:1–54
Schramm MW (1964) Paleogeologic and quantitative lithofacies analysis Simpson Group, Oklahoma. Bull Am Assoc Pet Geol 48(7):1164–1195
Sprinkle J (1982) Echinoderm zones and faunas. In: Sprinkle J (ed) Echinoderm Faunas from the Bromide Formation (Middle Ordovician) of Oklahoma. University of Kansas Paleontological Contributions, vol 1. Monograph, pp 47–56
Tobin RC (1982) A model for cyclic deposition in the Cincinnatian Series of southwestern Ohio, northern Kentucky, and southeastern Indiana. Unpublished PhD dissertation, University of Cincinnati 483 pp
Tucker M, Garland J (2010) High-frequency cycles and their sequence stratigraphic context: orbital forcing and tectonic controls on Devonian cyclicity, Belgium. Geol Belgica 13:213–240
Ulrich EO (1911) Revision of the Paleozoic systems. Geol Soc Am Bull 22:281–680
Vail PR, Audemard F, Bowman SA, Eisner PN, Perez-Cruz G (1991) The stratigraphic signatures of tectonics, eustasy and sedimentation—an overview. In: Einsele G, Ricken W, Seilacher A (eds) Cycles and events in stratigraphy. Springer, Berlin Heidelberg New York, pp 617–659
Van Wagoner JC, Posamentier HW, Mitchum RM, Vail PR, Sarg JF, Loutit TS, Hardenbol J (1988) An overview of sequence stratigraphy and key definitions. In: Wilgus CK, Hastings BS, Kendall CGSC, Posamentier HW, Ross CA, Wagoner JCV (eds) Sea Level Changes—an integrated approach. Special Publication, vol 42. Society of Economic Paleontologists and Mineralogists, pp 39–45
Walker KR (1972) Community ecology of the Middle Ordovician Black River Group of New York State. Geol Soc Am Bull 83:2499–2524
Williams M, Siveter DJ (1996) Lithofacies-influenced ostracod associations in the middle Ordovician Bromide Formation, Oklahoma, USA. J Micropalaeontology 15:69–81
Wright VP, Burchette TP (1996) Shallow-water carbonate environments. In: Reading HG (ed) Sedimentary environments: processes. Facies and Stratigraphy, Wiley-Blackwell, London, pp 368–378
Wright VP, Burgess PM (2005) The carbonate factory continuum, facies mosaics and microfacies: an appraisal of some of the key concepts underpinning carbonate sedimentology. Facies 51:17–23
Zecchin M (2007) The architectural variability of small-scale cycles in shelf and ramp clastic systems: the controlling factors. Earth Sci Rev 84:21–55
Zecchin M (2010) Towards the standardization of sequence stratigraphy: is the parasequence concept to be redefined or abandoned? Earth-Sci Rev 102:117–119
Zecchin M, Catuneanu O (2013a) High-resolution sequence stratigraphy of clastic shelves I: units and bounding surfaces. Mar Pet Geol 39:1–25
Zecchin M, Catuneanu O (2013b) High-resolution sequence stratigraphy of clastic shelves II: controls on sequence development. Mar Pet Geol 39:26–38
Acknowledgments
This research was funded by National Science Foundation grant EAR-0819715 to S. Westrop and C. Brett and a Geological Society of America research grant to J. Carlucci. A. Thomas, K. Carlucci, and S. Boyd assisted in fieldwork. Thanks to P. Koenigshof and M. Tucker for their suggestions which greatly improved the paper.
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Carlucci, J.R., Westrop, S.R., Brett, C.E. et al. Facies architecture and sequence stratigraphy of the Ordovician Bromide Formation (Oklahoma): a new perspective on a mixed carbonate-siliciclastic ramp. Facies 60, 987–1012 (2014). https://doi.org/10.1007/s10347-014-0412-6
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DOI: https://doi.org/10.1007/s10347-014-0412-6