Hostname: page-component-cd9895bd7-jkksz Total loading time: 0 Render date: 2024-12-17T20:42:03.577Z Has data issue: false hasContentIssue false

High-resolution correlation of the Homerian carbon isotope excursion (Silurian) across the interior of the Midland Platform (Avalonia), UK

Published online by Cambridge University Press:  29 October 2019

David C. Ray*
Affiliation:
School of Geography, Earth and Environmental Sciences, University of Birmingham, Edgbaston B15 2TT, United Kingdom
Emilia Jarochowska
Affiliation:
GeoZentrum Nordbayern, Fachgruppe Paläoumwelt, Universität Erlangen-Nürnberg, Loewenichstr. 28, 91054 Erlangen, Germany
Philipp Röstel
Affiliation:
GeoZentrum Nordbayern, Fachgruppe Paläoumwelt, Universität Erlangen-Nürnberg, Loewenichstr. 28, 91054 Erlangen, Germany
Graham Worton
Affiliation:
Dudley Museum and Art Gallery, The Archives and Local History Centre, Tipton Road, Dudley DY1 4SQ, United Kingdom
Axel Munnecke
Affiliation:
GeoZentrum Nordbayern, Fachgruppe Paläoumwelt, Universität Erlangen-Nürnberg, Loewenichstr. 28, 91054 Erlangen, Germany
James R. Wheeley
Affiliation:
School of Geography, Earth and Environmental Sciences, University of Birmingham, Edgbaston B15 2TT, United Kingdom
Ian Boomer
Affiliation:
School of Geography, Earth and Environmental Sciences, University of Birmingham, Edgbaston B15 2TT, United Kingdom
*
Author for correspondence: David C. Ray, Email: [email protected]

Abstract

New δ13Ccarb and microfacies data from Hereford–Worcestershire and the West Midlands allow for a detailed examination of variations in the Homerian carbon isotope excursion (Silurian) and depositional environment within the Much Wenlock Limestone Formation of the Midland Platform (Avalonia), UK. These comparisons have been aided by a detailed sequence-stratigraphic and bentonite correlation framework. Microfacies analysis has identified regional differences in relative sea-level change and indicates an overall shallowing of the carbonate platform interior from Hereford–Worcestershire to the West Midlands. Based upon the maximum δ13Ccarb values for the lower and upper peaks of the Homerian carbon isotope excursion (CIE), the shallower depositional setting of the West Midlands is associated with values that are 0.7 ‰ and 0.8 ‰ higher than in Hereford–Worcestershire. At the scale of parasequences the effect of depositional environment upon δ13Ccarb values can also be observed, with a conspicuous offset in the position of the trough in δ13Ccarb values between the peaks of the Homerian CIE. This offset can be accounted for by differences in relative sea-level change and carbonate production rates. While such differences complicate the use of CIEs as a means of high-resolution correlation, and caution against correlations based purely upon the isotopic signature, it is clear that a careful analysis of the depositional environment can account for such differences and thereby improve the use of carbon isotopic curves as a means of correlation.

Type
Original Article
Copyright
© Cambridge University Press 2019

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Aldridge, RJ, Siveter, DJ, Siveter, DJ, Lane, D, Palmer, DC and Woodcock, NH (2000) British Silurian Stratigraphy. Geological Conservation Review Series no. 19. Peterborough: Joint Nature Conservation Committee, 542 pp.Google Scholar
Bassett, MG, Bluck, BJ, Cave, R, Holland, CH and Lawson, JD (1992) Silurian. In Atlas of Palaeogeography and Lithofacies (eds Cope, JCW, Ingham, JK and Rawson, PF), pp. 3757. London: Geological Society, London Memoir 13.Google Scholar
Bergström, SM, Lehnert, O, Calner, M and Joachimski, MM (2012) A new upper Middle Ordovician–Lower Silurian drillcore standard succession from Borenshult in Östergötland, southern Sweden: 2. Significance of δ13C chemostratigraphy. GFF 134, 3963.CrossRefGoogle Scholar
Blain, JA, Ray, DC and Wheeley, JR (2016). Carbon isotope (δ13Ccarb) and facies variability at the Wenlock-Ludlow boundary (Silurian) of the Midland Platform, UK. Canadian Journal of Earth Sciences 53, 725–30.CrossRefGoogle Scholar
Buggisch, W and Mann, U (2004) Carbon isotope stratigraphy of Lochkovian to Eifelian limestones from the Devonian of central and southern Europe. International Journal of Earth Sciences (Geol Rundsch) 93, 521–44.Google Scholar
Butler, AJ (1939) The stratigraphy of the Wenlock Limestone at Dudley. Quarterly Journal of the Geological Society of London 95, 3474.CrossRefGoogle Scholar
Cocks, LRM, Holland, CH and Rickards, RB (1992) A Revised Correlation of Silurian Rocks in the British Isles. London: Geological Society of London, Special Report 21.CrossRefGoogle Scholar
Corfield, RM, Siveter, DJ, Cartlidge, JE and McKerrow, WS (1992) Carbon isotope excursion near the Wenlock-Ludlow, (Silurian) boundary in the Anglo-Welsh area. Geology 20, 371–4.2.3.CO;2>CrossRefGoogle Scholar
Cramer, BD, Brett, CE, Melchin, MA, Männik, P, Kleffner, MA, Mclaughlin, PI, Loydell, DK, Munnecke, A, Jeppsson, L, Corradini, C, Brunton, FR and Saltzman, MR (2011) Revised chronostratigraphic correlation of the Silurian System of North America with global and regional chronostratigraphic units and δ13Ccarb chemostratigraphy. Lethaia 44, 185202.CrossRefGoogle Scholar
Cramer, BD, Condon, DJ, Söderlund, U, Marshall, C, Worton, GW, Thomas, AT, Calner, M, Ray, DC, Perrier, V, Boomer, I, Patchett, PJ and Jeppsson, L (2012) U-Pb (zircon) age constraints on the timing and duration of Wenlock (Silurian) paleocommunity collapse and recovery during the ‘Big Crisis’. The Geological Society of America Bulletin 124, 1841–57.CrossRefGoogle Scholar
Cramer, BD, Kleffner, MA and Saltzman, MR (2006) The Late Wenlock Mulde positive carbon isotope (δ13Ccarb) excursion in North America. GFF 128, 8590.CrossRefGoogle Scholar
Da Silva, A-C and Boulvain, F (2008) Carbon isotope lateral variability in a Middle Frasnian carbonate platform (Belgium): significance of facies, diagenesis and sea-level history. Palaeogeography, Palaeoclimatology, Palaeoecology 269, 189204.CrossRefGoogle Scholar
Fry, CR, Ray, DC, Wheeley, JR, Boomer, I, Jarochowska, E and Loydell, DK (2017) The Homerian carbon isotope excursion (Silurian) within graptolitic successions on the Midland Platform (Avalonia), UK: implications for regional and global comparisons and correlations. GFF 139, 301–13.CrossRefGoogle Scholar
Frýda, J and Frýdova, B (2016) The Homerian (late Wenlock, Silurian) carbon isotope excursion from Perunica: does dolomite control the magnitude of the carbon isotope excursion? Canadian Journal of Earth Sciences 53, 695701.CrossRefGoogle Scholar
Holmden, C, Creaser, RA, Muehlenbachs, K, Leslie, SA and Bergstrom, SM (1998) Isotopic evidence for geochemical decoupling between ancient epeiric seas and bordering oceans: implications for secular curves. Geology 26, 567–70.2.3.CO;2>CrossRefGoogle Scholar
Huff, WD (2016) K-bentonites: a review. American Mineralogist 101, 4370.CrossRefGoogle Scholar
Hughes, HE and Ray, DC (2016) The carbon isotope and sequence stratigraphic record of the Sheinwoodian and lower Homerian stages (Silurian) of the Midland Platform, UK. Palaeogeography, Palaeoclimatology, Palaeoecology 445, 97114.CrossRefGoogle Scholar
Jarochowska, E and Munnecke, A (2015) Silurian carbonate high-energy deposits of potential tsunami origin: distinguishing lateral redeposition and time averaging using carbon isotope chemostratigraphy. Sedimentary Geology 315, 1428.CrossRefGoogle Scholar
Jarochowska, E, Ray, DC, Röstel, P, Worton, G and Munnecke, A (2017) Harnessing stratigraphic bias at the section scale: conodont diversity in the Homerian (Silurian) of the Midland Platform, England. Dryad Digital Repository. doi: 10.5061/dryad.7sd66.CrossRefGoogle Scholar
Jarochowska, E, Ray, DC, Röstel, P, Worton, G and Munnecke, A (2018) Harnessing stratigraphic bias at the section scale: conodont diversity in the Homerian (Silurian) of the Midland Platform, England. Palaeontology 61, 5776.CrossRefGoogle Scholar
Johnson, ME (2006) Relationship of Silurian sea fluctuations to oceanic episodes and events. GFF 128, 115–21.CrossRefGoogle Scholar
Kaljo, D and Martma, T (2006) Application of carbon isotope stratigraphy to dating the Baltic Silurian rocks. GFF 128, 123–9.CrossRefGoogle Scholar
Kozłowski, W and Sobień, K (2012) Mid-Ludfordian coeval carbon isotope, natural gamma ray and magnetic susceptibility excursions in the Mielnik IG-1 borehole (Eastern Poland): dustiness as a possible link between global climate and the Silurian carbon isotope record. Palaeogeography, Palaeoclimatology, Palaeoecology 339, 7497.CrossRefGoogle Scholar
Marshall, C, Thomas, AT, Boomer, I and Ray, DC (2012) High resolution δ13C stratigraphy of the Homerian (Wenlock) of the English Midlands and Wenlock Edge. Bulletin of Geosciences 87, 669–79.CrossRefGoogle Scholar
Melchin, MJ, Sadler, PM and Cramer, BD (2012) The Silurian period. In The Geologic Time Scale 2012 (eds Gradstein, FM, Ogg, JG, Schmitz, M and Ogg, G), pp. 525–58. New York: Elsevier.CrossRefGoogle Scholar
Oliver, PG (1981) Lithological groups within the Wenlock Limestone (Silurian) at Wren’s Nest. The Black Country Geologist, Black Country Geological Society 1, 3953.Google Scholar
Päßler, J-F, Jarochowska, E, Ray, DC, Munnecke, A and Worton, GJ (2014) Aphanitic buildup from the onset of the Mulde Event (Homerian, middle Silurian) at Whitman’s Hill, Herefordshire, UK: ultrastructural insights into proposed microbial fabrics. Estonian Journal of Earth Sciences 63, 287–92.CrossRefGoogle Scholar
Peng, SC and Babcock, LE (2011) Continuing progress on chronostratigraphic subdivision of the Cambrian System. Bulletin of Geosciences 86, 391–6.CrossRefGoogle Scholar
Penn, JSW (1971) Bioherms in the Wenlock Limestone of the Malvern area (Herefordshire, England). Mémoires du Bureau de Recherches Géologiques et Minières 73, 129–37.Google Scholar
Phipps, CB and Reeve, FAE (1967) Stratigraphy and geological history of the Malvern, Abberley and Ledbury Hills. Geological Journal 5, 339–68.CrossRefGoogle Scholar
Price, GD, Főzy, I and Pálfy, J (2016) Carbon cycle history through the Jurassic–Cretaceous boundary: a new global δ13C stack. Palaeogeography, Palaeoclimatology, Palaeoecology 451, 4661.CrossRefGoogle Scholar
Ratcliffe, KT (1988) Oncoids as environmental indicators in the Much Wenlock Limestone Formation of the English Midlands. Journal of the Geological Society, London 145, 117–24.CrossRefGoogle Scholar
Ratcliffe, KT and Thomas, AT (1999) Carbonate depositional environments in the late Wenlock of England and Wales. Geological Magazine 136, 189204.CrossRefGoogle Scholar
Ray, DC, Brett, CE, Thomas, AT and Collings, AVJ (2010) Late Wenlock sequence stratigraphy in central England. Geological Magazine 147, 123–44.CrossRefGoogle Scholar
Ray, DC, Collings, AVJ, Worton, GJ and Jones, G (2011) Upper Wenlock bentonites from Wren’s Nest Hill, Dudley; comparisons with prominent bentonites along Wenlock Edge, Shropshire, England. Geological Magazine 148, 670–81.CrossRefGoogle Scholar
Ray, DC, Richards, TD, Brett, CD, Morton, A and Brown, AM (2013) Late Wenlock sequence and bentonite stratigraphy in the Malvern, Suckley and Abberley Hills, England. Palaeogeography, Palaeoclimatology, Palaeoecology 389, 115–27.CrossRefGoogle Scholar
Ray, DC and Thomas, AT (2007) Carbonate depositional environments, sequence stratigraphy and exceptional skeletal preservation in the Much Wenlock Limestone Formation (Silurian) of Dudley, England. Palaeontology 50, 197222.CrossRefGoogle Scholar
Saltzman, MR and Thomas, E (2012) Carbon isotope stratigraphy. In The Geologic Time Scale 2012 (eds Gradstein, FM, Ogg, JG, Schmitz, M and Ogg, G), pp. 207–32. New York: Elsevier.CrossRefGoogle Scholar
Simmons, MD (2012) Sequence stratigraphy and sea-level change. In The Geologic Time Scale 2012 (eds Gradstein, FM, Ogg, JG, Schmitz, M and Ogg, G), pp. 239–67. New York: Elsevier.CrossRefGoogle Scholar
Stanley, GD and Lipps, JH (2011) Photosymbiosis: the driving force for reef success and failure. In Corals and Reef Crises, Collapse and Change (ed. Stanley, GD), pp. 3360. Boulder, Colorado: The Palaeontological Society.Google Scholar
Swart, PK (2008) Global synchronous changes in the carbon isotopic composition of carbonate sediments unrelated to changes in the global carbon cycle. Proceedings of the National Academy of Sciences, 105, 13741–45CrossRefGoogle ScholarPubMed
Torsvik, TH, Trench, A, Svensson, I and Walderhaug, HJ (1993) Palaeogeographic significance of mid-Silurian palaeomagnetic results from southern Britain: major revision of the apparent polar wander path for eastern Avalonia. Geophysical Journal International 113, 651–68.CrossRefGoogle Scholar
Vandenberghe, N, Hilgen, FJ and Speijer, RP (2012) The Paleogene period. In The Geologic Time Scale 2012 (eds Gradstein, FM, Ogg, JG, Schmitz, M and Ogg, G), pp. 855921. New York: Elsevier.CrossRefGoogle Scholar
Weissert, H, Joachimski, MM and Sarnthein, M (2008) Chemostratigraphy. Newsletters on Stratigraphy 42, 145–79.CrossRefGoogle Scholar
Supplementary material: PDF

Ray et al. supplementary material

Ray et al. supplementary material

Download Ray et al. supplementary material(PDF)
PDF 454 KB