Hostname: page-component-586b7cd67f-t7fkt Total loading time: 0 Render date: 2024-11-24T03:32:51.178Z Has data issue: false hasContentIssue false
  • English
  • Français

Perspectives on Cretaceous Gondwana break-up from detrital zircon provenance of southern Zealandia sandstones

Published online by Cambridge University Press:  13 May 2016

C.J. ADAMS ,
H J. CAMPBELL ,
N. MORTIMER  and
W.L. GRIFFIN
C.J. ADAMS
Affiliation:
GNS Science, Private Bag 1930, Dunedin 9054, New Zealand
H J. CAMPBELL*
Affiliation:
GNS Science, PO Box 30368, Lower Hutt 5040, New Zealand
N. MORTIMER
Affiliation:
GNS Science, Private Bag 1930, Dunedin 9054, New Zealand
W.L. GRIFFIN
Affiliation:
Australian Research Council Centre of Excellence for Core to Crust Fluid Systems/GEMOC, Department of Earth and Planetary Sciences, Macquarie University, NSW 2109, Australia
*
Author for correspondence: [email protected]
Get access Rights & Permissions [Opens in a new window]

Abstract

Detrital zircon U–Pb ages in 37 sandstones from late Early – Late Cretaceous marine and non-marine successions across southern Zealandia indicate a provenance from local basement within present-day Zealandia. Samples from Taranaki Basin were derived from Median and Karamea batholith granitoids with transport directions from west to east. Samples from West Coast, Western Southland and Great South basins contain components derived more locally and more variably from Median Batholith and Rahu Suite granitoids and/or the Palaeozoic Buller Terrane. West Coast Basin samples have more plutonic contributions and Great South Basin localities have more Albian-aged (c. 110–100 Ma) zircons. Samples from Canterbury Basin were sourced from Torlesse Composite Terrane basement. The provenance variations are present in both marine and non-marine sandstones and suggest localized watersheds. This fits an interpretation of Late Cretaceous deposition in rift-controlled basins across southern Zealandia during pre-Gondwana break-up regional extension. More speculatively, some additional source areas may have been created at the rifted margins of Zealandia during this break-up.

Keywords

CretaceousNew ZealandZealandiadetrital zirconU–Pb ages
Type
Original Articles
Information
Geological Magazine , Volume 154 , Issue 4 , July 2017 , pp. 661 - 682
Copyright
Copyright © Cambridge University Press 2016 

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

Adams, C. J., Campbell, H. J. & Griffin, W. L. 2007. Provenance comparisons of Permian to Jurassic tectonostratigraphic terranes in New Zealand: perspectives from detrital zircon age patterns. Geological Magazine 144, 701–29.Google Scholar
Adams, C. J., Campbell, H. J. & Griffin, W. L. 2009. Tracing the Caples Terrane through New Zealand using detrital zircon age patterns and radiogenic isotope signatures. New Zealand Journal of Geology and Geophysics 52, 223–45.CrossRefGoogle Scholar
Adams, C. J. & Griffin, W. L. 2012. Rodinian detrital zircons in Late Cretaceous sandstones indicate a possible Precambrian basement under southern Zealandia. Precambrian Research 212–213, 1320.Google Scholar
Adams, C. J., Mortimer, N., Campbell, H. J. & Griffin, W. L. 2013 a. Detrital zircon geochronology and sandstone provenance of basement Waipapa Terrane (Triassic–Cretaceous) and Cretaceous cover rocks (Northland Allochthon and Houhora Complex) in northern New Zealand. Geological Magazine 150, 89109.Google Scholar
Adams, C. J., Mortimer, N., Campbell, H. J. & Griffin, W.L. 2013 b. The mid-Cretaceous transition from basement to cover within sedimentary rocks in eastern New Zealand: evidence from detrital zircon age patterns. Geological Magazine 150, 455–78.Google Scholar
Adams, C. J., Mortimer, N., Campbell, H. J. & Griffin, W. L. 2015. Detrital zircon ages in Buller-Takaka terranes New Zealand: constraints on early Zealandia history. New Zealand Journal of Geology and Geophysics 58, doi: 10.1080/00288306.2015.1025798.Google Scholar
Adams, C. J., Seward, D. & Weaver, S. D. 1995. Geochronology of Cretaceous granites and metasedimentary basement on Edward VII Peninsula, Marie Byrd Land, West Antarctica. Antarctic Science 7, 265–77.Google Scholar
Bache, F., Mortimer, N., Sutherland, R., Collot, J., Rouillard, P., Stagpoole, V. M. & Nicol, A. 2014. Seismic stratigraphic record of transition from Mesozoic subduction to continental breakup in the Zealandia sector of eastern Gondwana. Gondwana Research 26, 1060–78.Google Scholar
Beggs, J. M. 1993. Depositional and tectonic history of the Great South Basin. In South Pacific Sedimentary Basins (ed. Ballance, P. F.), pp. 365–73. Amsterdam, Elsevier Science, Sedimentary Basins of the World no. 2.Google Scholar
Bell, J. M. & Fraser, C. 1906. The geology of the Hokitika Sheet, North Westland Quadrangle. New Zealand Geological Survey Bulletin 1, 1101.Google Scholar
Bialas, R. W., Buck, W. R., Studinger, M. & Fitzgerald, P. G. 2007. Plateau collapse model for the Transantarctic Mountains–West Antarctic Rift System: insights from numerical experiments. Geology 35, 687–90.Google Scholar
Bishop, D. G. 1986. Sheet B46 – Puysegur. Geological Map of New Zealand 1: 50 000 Wellington, New Zealand, Department of Scientific and Industrial Research.Google Scholar
Bishop, D. G., Bradshaw, J. D. & Landis, C. A. 1985. Provisional terrane map of South Island, New Zealand. In Tectonostratigraphic Terranes (ed. Howell, D. G.), pp. 515–21. Circum-Pacific Council for Energy and Mineral Resources, Earth Science Series, no. 1. Houston, Texas.Google Scholar
Bishop, D. G. & Turnbull, I. M. 1996. Geology of the Dunedin area. Institute of Geological & Nuclear Sciences 1: 250 000 Geological Map 21.Google Scholar
Bradshaw, J. D., Pankhurst, R. J., Weaver, S. D., Storey, B. C., Muir, R. J. & Ireland, T. R. 1997. New Zealand Superterranes recognised in Marie Byrd Land and Thurston Island. In The Antarctic Region: Geological Evolution and Processes (ed. Ricci, C. A.), pp. 429–36. Proceedings of the Seventh International Symposium on Antarctic Earth Sciences. Terra Antarctica Publication, Siena.Google Scholar
Browne, G. H., Kennedy, E. M., Constable, R. M., Raine, I., Crouch, E. M. & Sykes, R. 2010. An outcrop-based study of the economically significant Late Cretaceous Rakopi Formation, northwest Nelson, Taranaki Basin, New Zealand. New Zealand Journal of Geology and Geophysics 51, 295315.Google Scholar
Campbell, H. J., Andrews, P. B., Beu, A. G., Maxwell, P. A., Edwards, A. R., Laird, M. G., Hornibrook, N. de, B., Mildenhall, D. C., Watters, W. A., Buckeridge, J. S., Lee, D. E., Strong, C. P., Wilson, G. J. & Hayward, B. W. 1993. Cretaceous-Cenozoic Geology and Biostratigraphy of the Chatham Islands, New Zealand. Institute of Geological & Nuclear Sciences, Lower Hutt, Monograph no. 2, 269 pp.Google Scholar
Cawood, P. A., Nemchin, A. A., Leverenz, A., Saeed, A. & Ballance, P. F. 1999. U/Pb dating of detrital zircons: Implications for the provenance record of Gondwana margin terranes. Geological Society of America Bulletin 111, 1107–19.2.3.CO;2>CrossRefGoogle Scholar
Cook, R. A., Sutherland, R. & Zhu, R. 1999. Cretaceous-Cenozoic Geology and Petroleum Systems of the Great South Basin, New Zealand. Institute of Geological & Nuclear Sciences, Lower Hutt, Monograph no. 20, 188 pp.Google Scholar
Cooper, R. A. (compiler) 2004. A New Zealand Geological Timescale. Institute of Geological & Nuclear Sciences, Lower Hutt, Monograph no. 22, 284 pp.Google Scholar
Cox, S. C. & Barrell, D. J. A. (compilers) 2007. Geology of the Aoraki area. Institute of Geological & Nuclear Sciences 1:250 000 Geological Map 15.Google Scholar
Field, B. D., Browne, G. H., Davy, B., Herzer, R. H., Hoskins, R. H., Raine, J. I., Sewell, R. J., Smale, D., Watters, W. A. & Wilson, G. J. 1989. Cretaceous and Cenozoic Sedimentary Basins and Geological Evolution of the Canterbury Region, South Island, New Zealand. Institute of Geological & Nuclear Sciences, Lower Hutt, Basin Studies no. 2, 94 pp.Google Scholar
Forsyth, P. J. 2001. Geology of the Waitaki area. Institute of Geological & Nuclear Sciences 1: 250 000 Geological Map 19.Google Scholar
Forsyth, P. J., Barrell, D. J. A. & Jongens, R. (compilers) 2008. Geology of the Christchurch area. Institute of Geological & Nuclear Sciences 1: 250 000 Geological Map 16.Google Scholar
Gaina, C., Müller, D., Royer, J-Y., Stock, J., Hardebeck, J. & Symonds, P. 1998. The tectonic history of the Tasman Sea: a puzzle with thirteen pieces. Journal of Geophysical Research 103, 12412–33.Google Scholar
Gibson, G. M. & Ireland, T. R. 1995. Granulite formation during continental extension in Fiordland, New Zealand. Nature 375, 479–82.Google Scholar
Higgs, K. E., Arnot, M. J., Browne, G. H. & Kennedy, E. M. 2010. Reservoir potential of Late Cretaceous terrestrial to shallow marine sandstones, Taranaki Basin, New Zealand. Marine and Petroleum Geology 27 (9), 1849–71; doi:10.1016/j.marpetgeo.2010.08.002.Google Scholar
Hollis, C. J., Beu, A. G., Raine, J. I., Turnbull, I. M., Waghorn, D. B. & Wilson, G. J. 1997. Integrated biostratigraphy of Cretaceous-Paleogene strata on Campbell Island, Southwest Pacific. Institute of Geological & Nuclear Sciences, New Zealand, Science Report 97/25.Google Scholar
Ireland, T. R. & Gibson, G. M. 1998. SHRIMP monazite and zircon geochronology of high-grade metamorphism in New Zealand. Journal of Metamorphic Geology 16, 149–67.Google Scholar
Jackson, S. E., Pearson, N. J., Griffin, W. L. & Belousova, E. A. 2004. The application of laser ablation-inductively coupled plasma-mass spectrometry (LA-ICP-MS) to in situ U-Pb zircon geochronology. Chemical Geology 211, 4769.Google Scholar
King, P. R., Naish, T. R., Browne, G. H., Field, B. D. & Edbrooke, S. W. 1999. Cretaceous to Recent Sedimentary Patterns in New Zealand. Institute of Geological & Nuclear Sciences, Lower Hutt, Folio Series 1, version 1999.9.Google Scholar
King, P. R. & Thrasher, G. P. 1996. Cretaceous-Cenozoic Geology and Petroleum Systems of the Taranaki Basin, New Zealand. Institute of Geological & Nuclear Sciences, Lower Hutt, Monograph no. 13, 244 pp.Google Scholar
Laird, M. G. 1995. Coarse-grained lacustrine fan-delta deposits (Pororari Group) of the northwestern South Island, New Zealand: evidence for Mid-Cretaceous rifting. In: Sedimentary Facies Analysis: a Tribute to Research and Teaching of Harold G. Reading (ed. Plint, A. Guy). International Association of Sedimentologists, Special Publication no. 22, 197217.Google Scholar
Lindqvist, J. K. 1990. Mid-Cretaceous and Eocene-Oligocene stratigraphy, onshore Balleny Basin, south Fiordland. In Recent Developments in New Zealand Basin Studies Seminar (ed. Mazengarb, C. & Beggs, J. M.), pp. 45–7. DSIR Geology & Geophysics, Lower Hutt.Google Scholar
Lindqvist, J. K. & Douglas, B. J. 1987. Late Cretaceous-Paleocene Fluvial and Shallow Marine Deposits, Kaitangata Coalfield: Taratu and Wangaloa Formations. Field Trip Guide, Geological Society of New Zealand Dunedin conference. Geological Society of New Zealand, Miscellaneous Publication no. 37B.Google Scholar
Ludwig, K. R. 2003. User's Manual for ISOPLOT 3.00: A Geochronological Toolkit for Microsoft Excel. Berkeley Geochronology Centre, Special Publication no. 4.Google Scholar
Milne, A. D., Simpson, C. & Threadgold, P. 1975. Well completion reports Resolution-1. BP Shell Todd (Canterbury) Services Ltd. New Zealand Geological Survey, open file Petroleum Report no. 648.Google Scholar
Mortimer, N., Gans, P. B., Palin, J. M., Meffre, S., Herzer, R. H. & Skinner, D. N. B. 2010. Location and migration of Miocene-Quaternary volcanic arcs in the SW Pacific region. Journal of Volcanology and Geothermal Research 190, 110.Google Scholar
Mortimer, N., Rattenbury, M. S., King, P. R., Bland, K. J., Barrell, D. J. A., Bache, F., Begg, J. G., Campbell, H. J., Cox, S. C., Crampton, J. S., Edbrooke, S. W., Forsyth, P. J., Johnston, M. R., Jongens, R., Lee, J., Leonard, G. S., Raine, J. I., Skinner, D. N. B., Timm, C., Townsend, D. B., Tulloch, A. J., Turnbull, I. M. & Turnbull, R. E. 2014. High-level stratigraphic scheme for New Zealand rocks. New Zealand Journal of Geology and Geophysics 57, 402–19.Google Scholar
Mortimer, N., Tulloch, A. J. & Ireland, T. R. 1997. Basement geology of Taranaki and Wanganui Basins, New Zealand. New Zealand Journal of Geology and Geophysics 40, 223–68.Google Scholar
Mortimer, N., Tulloch, A. J., Spark, R. N., Walker, N. W., Ladley, E., Allibone, A. & Kimbrough, D. L. 1999. Overview of the Median Batholith, New Zealand: a new interpretation of the geology of the Median Tectonic Zone and adjacent rocks. Journal of African Earth Sciences 29, 257–68.Google Scholar
Muir, R. J., Ireland, T. R., Weaver, S. D. & Bradshaw, J. D. 1994. Ion microprobe zircon geochronology of granitic magmatism in the Western Province of the South Island, New Zealand. Chemical Geology (Isotope Geoscience Section) 113, 171–89.Google Scholar
Muir, R. J., Ireland, T. R., Weaver, S. D. & Bradshaw, J. D. 1996. Ion microprobe dating of Paleozoic granitoids: Devonian magmatism in New Zealand and correlations with Australia and Antarctica. Chemical Geology 127, 191210.Google Scholar
Muir, R. J., Ireland, T. R., Weaver, S. D., Bradshaw, J. D., Waight, T. E., Jongens, R. & Eby, G. N. 1997. U-Pb geochronology of Cretaceous magmatism in northwest Nelson-Westland, South Island, New Zealand. New Zealand Journal of Geology and Geophysics 40, 453–63.Google Scholar
Muir, R. J., Weaver, S. D., Bradshaw, J. D., Eby, G. N. & Evans, J. A. 1995. The Separation Point Batholith, New Zealand: granitoid magmas formed by the melting of mafic lithosphere. Journal of the Geological Society of London 152, 689701.Google Scholar
Nathan, S. 1978. Sheet S44 – Greymouth. Geological Map of New Zealand 1: 63 360 Wellington, New Zealand, Department of Scientific and Industrial Research.Google Scholar
Nathan, S., Anderson, H. J., Cook, R. A., Herzer, R. H., Hoskins, R. H., Raine, R. I. & Smale, D. 1986. Cretaceous and Cenozoic Sedimentary Basins of the West Coast Region, South Island, New Zealand. Institute of Geological & Nuclear Sciences Ltd., Lower Hutt, Basin Studies no. 1, 90 pp.Google Scholar
Nathan, S., Rattenbury, M. S., Jongens, R. & Suggate, R. P. (compilers) 2002. Geology of the Greymouth area. Institute of Geological & Nuclear Sciences 1: 250 000 Geological Map 12.Google Scholar
Norvick, M. S., Langford, R. P., Hashimoto, T., Rollet, N., Higgins, K. L. & Morse, M. P. 2008. New insights into the evolution of the Lord Howe Rise (Capel and Faust basins), offshore eastern Australia, from terrane and geophysical data analysis. PESA Eastern Australasian Basins Symposium III, Sydney, 14–17 September 2008, 291–309.Google Scholar
Norvick, M. S., Smith, M. A. & Power, M. R. 2001. The plate tectonic evolution of eastern Australia guided by the stratigraphy of the Gippsland basin. PESA Eastern Australasian Basins Symposium, Melbourne, 25–28 November 2001, 15–22.Google Scholar
Oliver, R. L. 1950. Preliminary report on the geology of Campbell Island. New Zealand Department of Scientific and Industrial Research. Cape Expedition Series Bulletin 3, 144.Google Scholar
Pankhurst, R. J., Weaver, S. D., Bradshaw, J. D., Storey, B. C. & Ireland, T. R. 1998. Geochronology and geochemistry of pre-Jurassic superterranes in Marie Byrd Land, Antarctica. Journal of Geophysical Research 103B, 2529–47.Google Scholar
Pickard, A. L., Adams, C. J. & Barley, M. E. 2000. Australian provenances for Upper Permian to Cretaceous rocks forming accretionary complexes on the New Zealand sector of the Gondwanaland margin. Australian Journal of Earth Sciences 47, 9871007.Google Scholar
Pole, M. 1992. Cretaceous macrofloras of eastern Otago. Australian Journal of Botany 40, 169206.Google Scholar
Raine, J. I. 1984. Outline of a palynological zonation of the Cretaceous to Paleogene terrestrial sediments in the West Coast region, South Island, New Zealand. New Zealand Geological Survey Report 109.Google Scholar
Raine, J. I., Beu, A. G., Boyes, A. F., Campbell, H. J., Cooper, R. A., Crampton, J. S., Crundwell, M. P., Hollis, C. J. & Morgans, H. E. G. 2015. Revised calibration of the New Zealand Geological Timescale NZGT2014. GNS Science Report 2012/39.Google Scholar
Rattenbury, M. S., Cooper, R. A. & Johnston, M. R. (compilers) 1998. Geology of the Nelson area. Institute of Geological & Nuclear Sciences 1: 250 000 Geological Map 9.Google Scholar
Rattenbury, M. S., Jongens, R. & Cox, S. C. (compilers) 2010. Geology of the Haast area. Institute of Geological & Nuclear Sciences 1: 250 000 Geological Map 14.Google Scholar
Rattenbury, M. S., Townsend, D. B. & Johnston, M. R. (compilers) 2006. Geology of the Kaikoura area. Institute of Geological & Nuclear Sciences 1: 250 000 Geological Map 13.Google Scholar
Richard, S. M., Smith, C. H., Kimbrough, D. L., Fitzgerald, P. G., Luyendyk, B. P. & McWilliams, M. O. 1994. Cooling history of the northern Ford Ranges, Marie Byrd Land, West Antarctica. Tectonics 13, 837–57.Google Scholar
Ritchie, D. D. & Turnbull, I. M. 1985. Cenozoic sedimentary rocks at Carnley Harbour, Auckland Islands, Campbell Plateau. New Zealand Journal of Geology and Geophysics 28, 2341.Google Scholar
Sahoo, T. R., King, P. R., Bland, K. J., Strogen, D. P., Sykes, R. & Bache, F. 2014. Tectono-sedimentary evolution and source rock distribution of the mid to Late Cretaceous succession in the Great South Basin, New Zealand. APPEA Journal and Conference Proceedings 54, 259–74.Google Scholar
Scott, J. M., Palin, J. M., Cooper, A. F. & King, R. P. 2009. Polymetamorphism, zircon growth and retention of early assemblages through the dynamic evolution of a continental arc in Fiordland, New Zealand. Journal of Metamorphic Geology 27, 281–94.Google Scholar
Sewell, R. J., Nathan, S. & Adams, C. J. 1988. Geochemistry of Late Cretaceous basaltic rocks from North Westland. New Zealand Geological Survey Record 35, 113–21.Google Scholar
Strogen, D. P., Baur, J. R., Bland, K. J. & King, P. R. 2011. Cretaceous-Paleogene: early rift to maximum flooding. In Strogen, D. P. (compiler). Paleogeographic synthesis of the Taranaki Basin and surrounds. GNS Science Report 2010/53, 11–35.Google Scholar
Sutherland, R. 1999. Basement geology and tectonic development of the greater New Zealand region: an interpretation from regional magnetic data. Tectonophysics 308, 341–62.Google Scholar
Sutherland, R., Stagpoole, V., Uruski, C., Kennedy, C., Bassett, D., Henrys, S., Scherwath, M., Kopp, H., Field, B., Toulmin, S., Barker, D., Bannister, S., Davey, F., Stern, T. & Flueh, E. 2009. Reactivation of tectonics, crustal underplating, and uplift after 60 Myr of passive subsidence, Raukumara Basin, Hikurangi-Kermadec fore arc, New Zealand: implications for global growth and recycling of continents. Tectonics 28, TC5017, doi: 10.1029/2008TC002356.Google Scholar
Tulloch, A. J., Beggs, J. M., Kula, J., Spell, T. & Mortimer, N. 2006. Cordillera Zealandia, the Sisters Shear Zone and their influence on the early development of the Great South Basin. In 2006 New Zealand Petroleum Conference Proceedings. Wellington: Ministry of Economic Development, p. 11.Google Scholar
Tulloch, A. J. & Kimbrough, D. L. 1989. The Paparoa Core Complex, New Zealand: cretaceous extension associated with the fragmentation of the Pacific Margin of Gondwana. Tectonics 8, 1217–34.Google Scholar
Tulloch, A. J., Ramezani, J., Mortimer, N., Mortensen, J., Van den Bogard, P. & Maas, R. 2009. Cretaceous felsic volcanism in New Zealand and Lord Howe Rise (Zealandia) as a precursor to final Gondwana break-up. In Extending a Continent, Architecture, Rheology and Heat Budgets (eds Ring, U. & Wernicke, R.), pp. 89118. Geological Society of London, Special Publication no. 21.Google Scholar
Turnbull, I. M., Allibone, A. H. 2003. Geology of the Murihiku area. Institute of Geological & Nuclear Sciences 1: 250 000 Geological Map 20.Google Scholar
Turnbull, I. M., Allibone, A. H. & Jongens, R. (compilers) 2010. Geology of the Fiordland area. Institute of Geological & Nuclear Sciences 1: 250 000 Geological Map 17.Google Scholar
Turnbull, I. M., Uruski, C. I., Anderson, H. J., Lindqvist, J. K., Scott, G. H., Morgans, H. E. G., Hoskins, R. H., Raine, J. I., Mildenhall, D. C., Pocknall, D. T., Beu, A. G., Maxwell, P. A., Smale, D., Watters, W. A. & Field, B. D. 1993. Cretaceous and Cenozoic Sedimentary Basins of Western Southland, South Island, New Zealand. Institute of Geological and Nuclear Sciences, Lower Hutt, Monograph no. 1, 86 pp.Google Scholar
Uruski, C. I. 2010. New Zealand's deepwater frontier. Marine and Petroleum Geology 27, 2005–26.CrossRefGoogle Scholar
Uruski, C. I. 2015. The contribution of offshore seismic data to understanding the evolution of the New Zealand continent. In Sedimentary Basins and Crustal Processes at Continental Margins: from Modern Hyper-extended Margins to Deformed Ancient Analogues (eds Gibson, G. M., Roure, F. & Manatschal, G.), pp. 3551. Geological Society of London, Special Publication no. 413.Google Scholar
Weaver, S. D., Adams, C. J., Pankhurst, R. J. & Gibson, I. L. 1992. Granites of Edward VII Peninsula, Marie Byrd Land: anorogenic magmatism related to Antarctic-New Zealand rifting. Transactions of the Royal Society of Edinburgh: Earth Sciences 83, 281–90.Google Scholar
Supplementary material: File

Adams supplementary material S1

Adams supplementary material

Download Adams supplementary material S1(File)
File 761.3 KB
Supplementary material: File

Adams supplementary material S2

Adams supplementary material

Download Adams supplementary material S2(File)
File 2.1 MB