Reconstruction of Ocean Plate Stratigraphy from the ancient orogen
Cui Hui-Qi1,2, Xu Shu-Mei1,2,3, Li San-Zhong1,2,3, Shu Peng-Cheng1,2, Ma Hui-Lei1,2, Kong Jia-Hao1,2
1 Key Lab of Submarine Geosciences and Prospecting Techniques,Ministry of Education, Ocean University of China, Shandong Qingdao 266100,China;
2 College of Marine Geosciences,Ocean University of China,Shandong Qingdao 266100,China;
3 Institute of Advanced Oceanography/Frontiers Science Center for Deep Ocean Multispheres and Earth System, Shandong Qingdao 266100,China
The paper focuses on reconstruction of the Oceanic Plate Stratigraphy (OPS)from the Precambrian accretionary complexes and mélange of ancient orogenic belts,including the Pacific OPS reconstructed from the Neoproterozoic Mona Supergroup mélange in Anglesey,Wales,United Kingdom,and the Paleo-Indian OPS reconstructed from the Early Archean Cleaverville greenstone belt,Pilbara,northwest Australia. The early Archean basalt-silicate-clastic sequence in the Marble Bar area of the East Pilbara Block of Australia is highly similar to the Permian-Triassic ocean plate strata of Japan in rock composition and geochemical characteristics. This conclusion will provide strong support for evolution of the sedimentary environments of the early Archean OPS from the high-heat flow ridge spreading area,through the hot spot,to the low-heat flow trench,terrigenous clastic depositional zone. According to the rock records of the OPS in the accretive orogenic belt,the main composition and rock types of the OPS strata from the Archean to the present are similar. Therefore,the processes of ocean spreading,deposition,subduction and accretion have not changed significantly during the Earth's 3.8-byr-history. However,the oceanic plate properties and the oceanic plate stratigraphic composition of young orogenic belts may have changed with time. Precambrian mantle temperature was slightly high,and the degree of partial melting was high in the Archean. The melting amount greatly exceeded the expansion rate of the ocean crust,so the sheet dike group did not form in ancient oceanic crust.
[1]Agard P,Yamato P,Jolivet L,Burov E.2009. Exhumation of ocean blueschists and eclogites in subduction zones: timing and mechanisms. Earth-Science Reviews, 92: 53-79.
[2]Asanuma H,Okada Y,Fujisaki W,Suzuki K,Sato T,Sawaki Y,Sakata S,Yamamoto S,Hirata T,Maruyama S,Windley B F.2015. Reconstruction of ocean plate stratigraphy in the Gwna Group,NW Wales: implications for the subduction and accretion process of a latest Pro terozoic trench forearc. Tectonophysics, 662: 195-207.
[3]Barley M E.1993. Volcanic,sedimentary and tectonostratigraphic environments of the 3.46 Ga Warrawoon a mega-sequence: a review. Precambrian Research, 60: 47-67.
[4]Blewett R S.2002. Archaean tectonic processes: a case for horizontal shortening in the North Pilbara Granite-Greenstone Terrane,Western Australia. Precambrian Research, 113: 87-120.
[5]Bolhar R,Von Kranendonk M J,Kamber B S.2005. A trace element study of siderite-jasper banded iron formation in the 3.45 Ga Warrawoona Group,Pilbara Craton: formation from hydrothermal fluids and shallow seawater. Precambrian Research, 137: 93-114.
[6]Bradley D C.2011. Secular trends in the geologic record and the supercontinent cycle. Earth-Science Reviews, 108: 16-33.
[7]Compston W,Wright A E,Toghill P.2002. Dating the Late Precambrian volcanicity of England and Wales. Journal of the Geological Society, 159(3): 323-339.
[8]Condon D,Prave A R.2000. Two from Donegal: Neoproterozoic glacial episodes on the northeast margin of Laurentia. Geology, 28: 951-954.
[9]Dallmeyer R D,Gibbons W.1987. The age of blueschist metamorphism on Anglesey,North Wales: evidence from 40Ar/39Ar mineral dates of the Penmynydd schists. Journal of Geological Society of London, 144: 843-850.
[10]Eriksson A,Hiatt E E,Laflamme M,Lenehard N,Long D G F,Miall A D,Mints M V,Pufahi P K,Sarkar S,Simpson E L, Williams G E.2012. Secular changes in sedimentation systems and sequence stratigraphy. Gondwana Research, 24: 468-489.
[11]Gibbons W,Hor$\acute{a}$k J M. 1996. The evolution of the Neoproterozoic Avalonian subduction system: evidence from the British Isles. In: Nance R D,Thompson M D(eds). A valonian and Related Peri-Gondwana Terranes of the Circum-North Atlantic. Geological Society of America Special Paper, 304: 269-280.
[12]Green M G,Sylvester P J,Buick R.2000. Growth and recycling of early Archaean continental crust: geochemical evidence from the Coonteru nah and Warrawoona Groups,Pilbara Craton,Australia. Tectonophysics, 322(1-2): 69-88.
[13]Greenly E.1919. The geology of Anglesey. Memoir,Geological Survey of Great Britain,2. London:HMSO,1-980.
[14]Kato Y,Ohta I,Tsunematsu T,Watanabe Y,Isozaki Y,Maruyama S,Imai N.1998. Rare earth element variations in mid-Archean banded iron formations: implications for the chemistry of ocean and continent and platetectonics. Geochimica et Cosmochimica Acta, 62: 3475-3497.
[15]Kato Y,Nakao K,Isozaki Y.2002. Geochemistry of Late Permian to Early Triassic pelagic cherts from southwest Japan: implications for an oceanic redox change. Chemical Geology, 182(1): 15-34.
[16]Kato Y,Nakamura K.2003. Origin and global tectonic significance of Early Archean cherts from the Marble Bar greenstone belt,Pilbara Craton,Western Australia. Precambrian Research, 125(3-4): 191-243.
[17]Kawai T,Windley B F,Terabayashi M,Yamamoto H,Maruyama S,Isozaki Y.2006. Mineral isograds and metamorphic zones of the Anglesey blueschist belt,UK: implications for the metamorphic development of a Neoproterozoic subduction-accretion complex. Journal of Metamorphic Geology, 24: 591-602.
[18]Kawai T,Windley B F,Terabayashi M,Yamamoto H,Maruyama S,Omori S,Shibuya T,Sawaki Y,Isozaki Y.2007. Geotectonic framework of the Blueschist Unit on Anglesey-Lleyn,UK,and its role in the deve lopment of a Neoproterozoic accretionary orogen. Precambrian Research, 153: 11-28.
[19]Kimura K,Hori R.1993. Offscraping accretion of Jurassic chert-clastic complexes in the Mino-Tamba Belt,central Japan. Journal of Structural Geology, 15(2): 145-161.
[20]Kimura G,Maruyama S,Isozaki Y,Terabayashi M.1996. Well-preserved underplating structure of the jadeitized Franciscan complex,Pacheco Pass,California. Geology, 24(1): 75-78.
[21]Kitajima K,Maruyama S,Utsunomiya S,Liou J G.2001. Seafloor hydrothermal alteration at an Archaean mid-ocean ridge. Journal of Metamorphic Geology, 19(5): 583-599.
[22]Krapez B,Eisenlohr B.1998. Tectonic setting of Archaean(3325-2775 Ma)crustal-supracrustal belts in the West Pilbara Block. Precambrian Research, 88: 173-205.
[23]Kusky T M,Windley B F,Safonova I,Wakita K,Wakabayashi J,Polat A,Santosh M.2013. Recognition of ocean plate stratigraphy in accretionary orogens through Earth history: a record of 3.8 billion years of sea floor spreading,subduction,and accretion. Gondwana Research, 24: 501-547.
[24]Maruyama S,Kawai T,Windley B F.2010. Ocean plate stratigraphy and its imbrication in an accretionary orogen: the Mona Complex,Anglesey-Lleyn,Wales,UK. In: Kusky T M,Zhai M G,Xiao W(eds). The Evolving Continents: Understanding Processes of Continental Growth. Geological Society,London,Special Publications, 338: 55-75.
[25]Matsuda T,Isozaki Y.1991. Well-documented travel history of Mesozoic pelagic chert in Japan: from remote ocean to subduction zone. Tectonics, 10: 475-499.
[26]Ohta H,Maruyama S,Takashi E,Watanabe Y,Kato Y.1996. Field occurrence,geochemistry and petrogenesis of the Archean Mid-Oceanic Ridge Basalts(AMORBs)of the Cleaverville area,Pilbara Craton,Western Australia. Lithos, 37(2-3): 199-221.
[27]Osozawa S.1994. Plate reconstruction based upon age data of Japanese accretionary complexes. Geology, 22: 1135-1138.
[28]Robinson P,Malpas J,Dilek Y.2008. The significance of sheeted dike complexes in ophiolites. GSA Today, 18: 4-10.
[29]Strachan R A,Taylor G K(eds). 1990. Avalonian and Cadomian Geology of the North Atlantic. Blackie,Glasgow:1-252.
[30]Terabayashi M,Masafa Y,Ozawa H.2003. Archean ocean-floor metamorphism in the North Pole area,Pilbara Craton,Western Australia. Precambrian Research, 127: 167-180.
[31]Trindada R I F,Macouin M.2007. Palaeolatitude of glacial deposits and palaeogeography of Neoproterozoic ages. Comptes Rendus Geoscience, 339: 200-211.
[32]Tucker R D,Pharaoh T C.1991. U-Pb zircon ages for Late Precambrian igneous rocks in southern Britain. Journal of Geological Society of London, 148: 435-443.
[33]Wagoner Kranendonk M J,Smithies R H,Hickman A H,Champion D C. 2007. Paleoarchean development of a continental nucleus: the East Pilbara terrane of the Pilbara Craton,western Australia. In: Wagoner Kranendonk M J,Smithies R H,Bennett V C(eds).Earth’s Oldest Rocks. Amsterdam: Elsevier,307-337.
[34]Wood M.2012. The historical development of the term‘mélange’ and its relevance to the Precambrian geology of Anglesey and the Lleyn Peninsula in Wales, UK. Journal of Geography, 121: 168-180.
[35]Young G M.2012. Secular changes at the Earth’s surface: evidence from palaeosols,some sedimentary rocks,and paleoclimatic perturbations of the Proterozoic Eon. Gondwana Research, 24: 453-467.