Abstract
It has been proposed that the North China Craton (NCC) was thinned up to a thickness of >100 km during the Phanerozoic, and underwent an associated craton destruction. Evidently, it is an important topic worthy of future study to understanding the mechanism of cratonic destruction and its role played in the continental evolution. After synthesized the global cratons of India, Brazil, South Africa, Siberia, East Europe (Baltic) and North America, we found that lithospheric thinning is common in the cratonic evolution, but it is not always associated with craton destruction. Most cratons was thinned by thermal erosion of mantle plume or mantle upwelling, which, however, may not cause craton destruction. Based on the studies of the North American and North China Cratons, we suggest that oceanic subduction plays an important role in caton destruction. Fluids or melts released by dehydration of the subducted slabs metasomatize the mantle wedge above and trigger extensive partial melting. More importantly, the metasomatized mantle lost its original rigidity and make craton easier to be deformed and then to be destoyed. Therefore, we suggest that the widespread crust-derived granite and large-scale ductile deformation within the continental crust can be regarded as the petrological and structural indicators of craton destruction, respectively.
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Agashev A M, Ionov D A, Pokhilenko N P, et al. 2013. Metasomatism in lithospheric mantle roots: Constraints from whole-rock and mineral chemical composition of deformed peridotite xenoliths from kimberlite pipe Udachnaya. Lithos, 160–161: 201–215
Artemieva I M. 2003. Lithospheric structure, composition, and thermal regime of the East European Craton: Implications for the subsidence of the Russian platform. Earth Planet Sci Lett, 213: 431–446
Arzamastsev A A, Bea F, Glaznev V N, et al. 2001. Kola alkaline province in the Palaeozoic: Evaluation of primary mantle magma composition and magma generation conditions. Russ J Earth Sci, 3: 1–32
Ashchepkov I V, Pokhilenko N P, Vladykin N V, et al. 2010. Structure and evolution of the lithospheric mantle beneath Siberian Craton, thermobarometric study. Tectonophysics, 485: 17–41
Basu A R, Poreda R J, Renne P R, et al. 1995. High-3He plume origin and temporal-spatial evolution of the Siberian flood basalts. Science, 269: 822–825
Begg G C, Griffin W L, Natapov L M, et al. 2009. The lithospheric architecture of Africa: Seismic tomography, mantle petrology, and tectonic evolution. Geosphere, 5: 23–50
Bell D R, Schmitz M D, Janney P E. 2003. Mesozoic thermal evolution of the southern African lithosphere. Lithos, 71: 273–287
Bird P. 1979. Continental delamination and the Colorado Plateau. J Geophys Res, 84: 7561–7571
Bleeker W. 2003. The Late Archean record: A puzzle in ca. 35 pieces. Lithos, 71: 99–134
Boyd F R. 1984. Siberian geotherm based on lherzolite xenoliths from the Udachnaya kimberlite, USSR. Geology, 12: 528–530
Boyd F R, Pokhilenko N P, Pearson D G, et al. 1997. Composition of the Siberian cratonic mantle: Evidence from Udachnaya peridotite xenoliths. Contrib Mineral Petrol, 128: 228–246
Boyd O S, Jones C H, Sheehan A F. 2006. Foundering lithosphere imaged beneath the southern Sierra Nevada, California, USA. Science, 305: 660–662
Campbell I H. 2007. Testing the plume theory. Chem Geol, 241: 153–176
Carlson R W, Pearson D G, James D E. 2005. Physical, chemical, and chronological characteristics of continental mantle. Rev Geophys, 43, doi: 10.1029/2004RG000156
Carlson R W, Irving A J. 1994. Depletion and enrichment history of subcontinental lithospheric mantle: An Os, Sr, Nd and Pb isotopic study of ultramafic xenoliths from the northwestern Wyoming craton. Earth Planet Sci Lett, 126: 457–472
Chalapathi Rao N V, Wu F Y, Mitchell R H, et al. 2013. New Mesoproterozoic U-Pb ages, chemical and Sr-Nd isotopic composition of perovskite from kimberlites of the Eastern Dharwar craton, Southern India: Distinct mantle sources and a widespread 1.1 Ga tectonothermal event. Chem Geol, 353: 48–64
Chen B, Niu X L, Wang Z Q, et al. 2013. Geochronology, petrology, and geochemistry of the Yaojiazhuang ultramafic-syenitic complex from the North China Craton. Sci China Earth Sci, 56: 1294–1307
Chen L, Wang T, Zhao L, et al. 2008. Distinct lateral variation of lithospheric thickness in the northeastern North China Craton. Earth Planet Sci Lett, 267: 56–68
Cordeiro P F D, Brod J A, Palmieri M, et al. 2011. The Catalao I niobium deposit, central Brazil: Resources, geology and pyrochlore chemistry. Ore Geol Rev, 41: 112–121
Courtillot V, Besse J, Vandamme D, et al. 1986. Deccan flood basalts at the Cretaceous/Tertiary boundary? Earth Planet Sci Lett, 80: 361–374
Courtillot V, Kravchinsky V A, Quidelleur X, et al. 2010. Preliminary dating of the Viluy traps (Eastern Siberia): Eruption at the time of Late Devonian extinction events? Earth Planet Sci Lett, 300: 239–245
Davies G F. 1994. Thermomechanical erosion of the lithosphere by mantle plumes. J Geophys Res, 99: 15709–15722
De Almeida F F M, Neves B B D, Carneiro C D. 2000. The origin and evolution of the South American Platform. Earth-Sci Rev, 50: 77–111
Dessai A G, Markwick A, Vaselli O, et al. 2004. Granulite and pyroxenite xenoliths from the Deccan Trap: Insight into the nature and composition of the lower lithosphere beneath cratonic India. Lithos, 78: 263–290
De Wit M J, Roering C, Hart R J, et al. 1992. Formation of an Archaean continent. Nature, 357: 553–562
Dickinson W R. 2004. Evolution of the north American cordillera. Annu Rev Earth Planet Sci, 32: 13–45
Doucet L S, Ionov D A, Golovin A V. 2013. The origin of coarse garnet peridotites in cratonic lithosphere: New data on xenoliths from the Udachnaya kimberlite, central Siberia. Contrib Mineral Petrol, 165: 1225–1242
Downes H, Balaganskaya E, Beard A, et al. 2005. Petrogenetic processes in the ultramafic, alkaline and carbonatitic magmatism in the Kola alkaline province: A review. Lithos, 85: 48–75
Downes H, MacDonald R, Upton B G J, et al. 2004. Ultramafic xenoliths from the Bearpaw Mountains, Montana, USA: Evidence for multiple metasomatic events in the lithospheric mantle beneath the Wyoming craton. J Petrol, 45: 1631–1662
Ducea M, Saleeby J. 1998. A case for delamination of the deep batholithic crust beneath the Sierra Nevada, California. Int Geol Rev, 40: 78–93
Duebendorfer E M, Houton R S. 1987. Proterozoic accretionary tectonics at the southern margin of the Archean Wyoming craton. Geol Soc Am Bull, 98: 554–568
Duncan R A, Pyle D G. 1988. Rapid eruption of the Deccan flood basalts at the Cretaceous/Tertiary boundary. Nature, 333: 841–843
Elkins-Tanton L T. 2005. Continental magmatism caused by lithospheric delamination. In: Foulger G R, Natland J H, Presnall D C, et al., eds. Plates, Plumes, and Paradigms. Geol Soc Am Special Paper, 388: 449–461
Ellam R M. 1992. Lithospheric thickness as a control on basalt geochemistry. Geology, 20: 153–156
Fouch M J, James D E, VanDecar J C, et al. 2004. Mantle seismic structure beneath the Kaapvaal and Zimbabwe cratons. S Afr J Geol, 107: 33–44
Frost C D, Frost B R, Chamberlain K R, et al. 1998. The late Archean history of the Wyoming province as recorded by granitic magmatism in the Wind River Range, Wyoming. Precambrian Res, 89: 145–173
Gibson S A, Thompson R N, Leonardos O H, et al. 1995. The Late Cretaceous impact of the Trindade mantle plume: Evidence from large-volume, mafic, potassic magmatism in SE Brazil. J Petrol, 36: 189–229
Gibson S A, Thompson R N, Day J A. 2006. Timescales and mechanisms of plume-lithosphere interactions: 40Ar/39Ar geochronology and geochemistry of alkaline igneous rocks from the Paraná-Etendeka large igneous province. Earth Planet Sci Lett, 251: 1–17
Gokarn S G, Gupta G, Rao C K. 2004. Geoelectric structure of the Dharwar craton from magnetotelluric studies: Archean suture identified along the Chitradurga-Gadagschist belt. Geophys J Int, 158: 712–758
Griffin W L, Zhang A D, O’Reilly S Y, et al. 1998. Phanerozoic evolution of the lithosphere beneath the Sino-Korean craton. In: Flower M F J, Chung S L, Lo C H, et al., eds. Mantle Dynamics and Plate Interactions in East Asia. Am Geophy Union, 27: 107–126
Griffin W L, Ryan C G, Kaminsky F V, et al. 1999. The Siberian lithosphere traverse: Mantle terranes and the assembly of the Siberian Craton. Tectonophysics, 310: 1–35
Griffin W L, Natapov L M, O’Reilly S Y, et al. 2005. The Kharamai kimberlite field, Siberia: Modification of the lithospheric mantle by the Siberian Trap event. Lithos, 81: 167–187
Griffin W L, Kobussen A F, Babu E V, et al. 2009. A translithospheric suture in the vanished 1-Ga lithospheric root of South India: Evidence from contrasting lithosphere sections in the Dharwar Craton. Lithos, 112S: 1109–1119
Guarino V, Wu F Y, Lustrino M, et al. 2013. U-Pb ages, Sr-Nd- isotope geochemistry and petrogenesis of kimberlites, kamafugites and phlogopite-picrites of the Alto Paranaíba Igneous Province, Brazil. Chem Geol, 353: 65–82
Hanson R E, Harmer R E, Blenkinsop T G, et al. 2006. Mesoproterozoic intraplate magmatism in the Kalahari craton: A review. J Afr Earth Sci, 46: 141–167
Harte B. 2010. Diamond formation in the deep mantle: The record of mineral inclusions and their distribution in relation to mantle dehydration zones. Mineral Mag, 74: 189–215
Heaman L M, Machado N. 1992. Timing and origin of Midcontinent Rift alkaline magmatism, North America: Evidence from the Coldwell Complex. Contrib Mineral Petrol, 110: 289–303
Heaman L M, LeCheminant A N. 1993. Paragenesis and U-Pb systematics of baddeleyite (ZrO2). Chem Geol, 110: 95–126
Heaman L M, LeCheminant A N, Rainbird R H. 1992. Nature and timing of Franklin igneous events, Canada: Implications for a Late Proterozoic mantle plume and the break-up of Laurentia. Earth Planet Sci Lett, 109: 117–131
Heaman L M, Kjarsgaard B A, Creaser R A. 2003. The timing of kimberlite magmatism and implications for diamond exploration: A global perspective. Lithos, 71: 153–184
Heaman L M, Kjarsgaard B A, Creaser R A. 2004. The temporal evolution of North American kimberlites. Lithos, 76: 377–397
Hooper P, Widdowson M, Kelley S. 2009. Tectonic setting and timing of the final Deccan flood basalt eruptions. Geology, 38: 839–842
Howarth G H, Barry P H, Pernet-Fisher J F, et al. 2014. Superplume metasomatism: Evidence from Siberian mantle xenoliths. Lithos, 184/187: 209–224
Ionov D A, Doucet L S, Ashchepkov I V. 2010. Composition of the lithospheric mantle in the Siberian craton: New constraints from fresh peridotites in the Udachnaya-East kimberlite. J Petrol, 51: 2177–2210
Jourdan F, Feraud G, Bertrand H, et al. 2005. The Karoo large igneous province: Brevity, origin, and relation with mass extinction questioned by new 40Ar/39Ar age data. Geology, 33: 745–748
Karmalkar N R, Griffin W L, O’Reilly S Y. 2000. Ultramafic xenoliths from Kutch (NW India): Plume-related mantle samples? Int Geol Rev, 42: 416–444
Karmalkar N R, Duraiswami R A, Chalapathi Rao N V, et al. 2009. Mantle-derived mafic-ultramafic xenoliths and the nature of Indian sub-continental Lithosphere. J Geol Soc India, 73: 657–679
Kiselev S, Vinnik L, Oreshin S, et al. 2008. Lithosphere of the Dharwar craton by joint inversion of P and S receiver functions. Geophys J Int, 173: 1106–1118
King S D, Anderson D L. 1998. Edge-driven convection. Earth Planet Sci Lett, 160: 289–296
Krystopowicz N J, Currie C A. 2013. Crustal eclogitization and lithosphere delamination in orogens. Earth Planet Sci Lett, 361: 195–207
Kumar A, Heaman L M, Manikyamba C. 2007a. Mesoproterozoic kimberlites in south India: A possiblr link to ∼1.1 Ga global magmatism. Precambrian Res, 154: 192–204
Kumar P, Yuan S, Kumar M R, et al. 2007b. The rapid drift of the Indian tectonic plate. Nature, 449: 894–897
Lee C T, Yin Q Z, Rudnick R L, et al. 2000. Osmium isotopic evidence for Mesozoic removal of lithospheric mantle beneath the Sierra Nevada, California. Science, 289: 1912–1916
Lee C T, Luffi P, Chin E J. 2011. Building and destroying continental mantle. Annu Rev Earth Planet Sci, 39: 59–90
Lenardic A, Moresi L N, Mühlhaus H. 2003. Longevity and stability of cratonic lithosphere: Insights from numerical simulations of coupled mantle convection and continental tectonics. J Geophys Res, 108, doi: 10.1029/2002JB001859
Li H Y. 2013. Destruction of North China Craton: Insights from temporal and spatial evolution of the proto-basins and magmatism. Sci China Earth Sci, 56: 464–478
Lu F X, Han Z G, Zheng J P, et al. 1991. Characteristics of the aleozoic mantle-lithosphere in Fuxian, Liaoning Province (in Chinese with English abstract). Geol Sci Tech Info, 10(Suppl): 2–20
Ma X, Chen B, Chen J F, et al. 2013. Zircon SHRIMP U-Pb age, geochemical, Sr-Nd isotopic, and in-situ Hf isotopic data of the Late Carboniferous-Early Permian plutons in the northern margin of the North China Craton. Sci China Earth Sci, 56: 126–144
McKenzie D, Bickle M J. 1988. The volume and composition of melt generated by extension of the lithosphere. J Petrol, 29: 625–679
Menzies M A, Fan W M, Zhang M. 1993. Palaeozoic and Cenozoic lithoprobe and the loss of >120 km of Archean lithosphere, Sino-Korean craton, China. In: Prichard H M, Alabaster T, Harris N B W, et al., eds. Magmatic Processes and Plate Tectonic. Geol Soc Special Publ, 76: 71–81
Morbidelli L, Gomes C B, Beccaluva L, et al. 1995. Mineralogical, petrological and geochemical aspects of alkaline and alkaline-carbonatite association from Brazil. Earth-Sci Rev, 39: 135–168
Mukherjee A B, Biswas S K. 1988. Mantle derived spinel lherzolite xenoliths from the Deccan volcanic province (India): Implications for the thermal structure of the lithosphere underlying the Deccan trap. J Volcanol Geotherm Res, 35: 269–276
Nehru C E, Reddy A K. 1989. Ultramafic xenoliths from Wajrakarur kimberlites, India. In: Ross J, Jacques A L, Ferguson J, et al, eds. Kimberlites and Related Rocks, Proceedings of the Fourth International Kimberlite Conference. vol. 2. Geol Soc Australia Special Publ, 14: 745–759
O’Brien H E, Irving A J, McCallum I S, et al. 1995. Stronium, neodymium, and lead isotopic evidence for the interaction of post-subduction asthernospheric potassic mafic magmas of the Highwood Mountains, Montana, USA, with ancient Wyoming craton lithospheric mantle. Geochim Cosmochim Acta, 59: 4539–4556
Pearson D G, Canil D, Shirey S B. 2003. Mantle samples included in volcanic rocks: Xenoliths and diamonds. In: Carlson R W, ed. Treatise on Geochemistry: The Mantle and Core. Amsterdam: Elsevier. 171–276
Peslier A H, Woodland A B, Bell D R, et al. 2009. Olivine water contents in the continental lithosphere and the longevity of cratons. Nature, 467: 78–81
Petitjean S, Rabinowicz M, Grégoire M, et al. 2006. Differences between Archean and Proterozoic lithospheres: Assessment of the possible major role of thermal conductivity. Geochem Geophys Geosyst, 7: Q03021, doi: 10.1029/2005GC001053
Qiao Y C, Guo Z Q, Shi Y L. 2013. Thermal convection thinning of the North China Craton: Numerical simulation. Sci China Earth Sci, 56: 773–782
Rajesh H M, Mukhopadhyay J, Beukes N J, et al. 2009. Evidence for an early Archaean granite from bastar craton, India. J Geol Soc London, 166: 193–196
Rao K R P, Rao K N, Dhakate M V, et al. 2001. Petrology and mineralogy of mantle xenoliths of Wajrakarur and Narayanpet kimberlite fields, Andhra Pradesh, India. Geol Survey India Special Publ, 58: 577–591
Read G, Grutter H, Winter S, et al. 2004. Stratigraphic relations, kimberlite emplacement and lithospheric thermal evolution, Quirico Basin, Minas Gerais State, Brazil. Lithos, 77: 803–818
Reichow M K, Pringle M S, Al’Mukhamedov A I, et al. 2009. The timing and extent of the eruption of the Siberian Traps large igneous province: Implications for the end-Permian environmental crisis. Earth Planet Sci Lett, 277: 9–20
Renne P R, Zhang Z C, Richards M A, et al. 1995. Synchrony and causal relations between Permian-Triassic boundary crises and Siberian flood volcanism. Science, 269: 1413–1416
Rosen O M, Manakov A V, Serenko V P. 2005. Paleoproterozoic collisional system and diamondiferous lithospheric keel of the Yakutian kimberlite province. Russ Geol Geophys, 46: 1259–1272
Roy S, Rao R. 2000. Heat flow in the Indian Shield. J Geophys Res, 105: 25587–25604
Sarkar D, Chandrakala K, Padmavathi, et al. 2001. Crustal velocity structure of western Dharwar Craton, South India. J Geodyn, 31: 227–241
Sarkar R K, Saha D K. 2006. A note of the lithosphere thickness and heat flow density of the Indian Craton from MAGSAT data. Acta Geophy, 54: 198–204
Saunders A D, England R W, Reichow M K, et al. 2005. A mantle plume origin for the Siberian Traps: Uplift and extension in the West Siberian Basin, Russia. Lithos, 79: 407–424
Schoene B, de Wit M, Bowring S A. 2008. Mesoarchean assembly and Stabilization of the eastern Kaapvaal craton: A structural-thermochronological perspective. Tectonics, 27: TC5010, doi: org/10.1029/2008TC002267
Sengor A M C. 1997. Continental interiors and cratons: Any relation? Tectonophysics, 305: 1–42
Shalivahan, Bhattacharya B B, Chalapathi Rao N V, et al. 2014. Thin lithosphere-asthenosphere boundary beneath Eastern Indian craton. Tectonophysics, 612/613: 128–133
Sleep N H. 2005. Evolution of the continental lithosphere. Annu Rev Earth Planet Sci, 33: 369–393
Sonder L J, Jones C H. 1999. Western United States extension: How the West was widened. Annu Rev Earth Planet Sci, 27: 417–462
Sun J, Liu C Z, Tappe S, et al. 2014. Repeated kimberlite magmatism beneath Yakutia and its relationship to Siberian flood volcanism: Insights from in situ U-Pb and Sr-Nd perovskite isotope analysis. Earth Planet Sci Lett, 404: 283–295
Svensen H, Corfu F, Polteau S, et al. 2012. Rapid magma emplacement in the Karoo large igneous province. Earth Planet Sci Lett, 325/326: 1–9
Taylor L A, Snyder G A, Keller R, et al. 2003. Petrogenesis of group A eclogites and websterites: Evidence from the Obnazhennaya kimberlite, Yakutia. Contrib Mineral Petrol, 145: 424–443
Torsvik T H, Burke K, Steinberger B, et al. 2010. Diamonds sampled by plumes from the core-mantle boundary. Nature, 466: 352–355
Tychkov N S, Pokhilenko N P, Kuligin S S, et al. 2008. Composition and origin of peculiar pyropes from lherzolites: Evidence for the evolution of the lithospheric mantle of the Siberian Platform. Russ Geol Geophys, 49: 225–239
Ulbrich H H G J, Gomes C B. 1981. Alkaline rocks from continental Brazil. Earth-Sci Rev, 17: 135–154
Walter M J, Kohn S C, Araujo D, et al. 2011. Deep mantle recycling of oceanic crust: Evidenc from diamonds and their mineral inclusions. Science, 334: 54–57
Wang T, Guo L, Zheng Y D, et al. 2012. Timing and processes of late Mesozoic mid-lower-crustal extension in continental NE Asia and implications for the tectonic setting of the destruction of the North China Craton: Mainly constrained by zircon U-Pb ages from metamorphic core complexes. Lithos, 154: 315–345
Wu F Y, Lin J Q, Wilde S A, et al. 2005. Nature and significance of the Early Cretaceous giant igneous event in eastern China. Earth Planet Sci Lett, 233: 103–119
Wu F Y, Xu Y G, Gao S, et al. 2008. Lithospheric thinning and destruction of the North China Craton. Acta Petrol Sin, 24: 1145–1174
Wu F Y, Yang Y H, Li Q L, et al. 2011. In situ determination of U-Pb ages and Sr-Nd-Hf isotopic constraints on the petrogenesis of the Phalaborwa carbonatite Complex, South Africa. Lithos, 127: 309–322
Wu F Y, Mitchell R H, Li Q L, et al. 2013a. In situ U-Pb age determination and Sr-Nd isotopic analyses of perovskite from the Premier (Cullinan) kimberlite, South Africa. Chem Geol, 353: 83–95
Wu F Y, Arzamastsev A A, Mitchell R H, et al. 2013b. Emplacement age and Sr-Nd isotopic compositions of the Afrikanda alkaline ultramafic complex, Kola Peninsula, Russia. Chem Geol, 353: 210–229
Xia Q K, Hao Y T, Li P, et al. 2010. Low water content of the Cenozoic lithospheric mantle beneath the eastern part of the North China Craton. J Geophys Res, 115: B07207, doi: 10.1029/2009JB006694
Xia Q K, Liu J, Liu S C, et al. 2013. High water content in Mesozoic primitive basalts of the North China Craton and implications on the destruction of cratonic mantle lithosphere. Earth Planet Sci Lett, 361: 85–97
Xu Y G, He B, Chung S L, et al. 2004. Geologic, geochemical, and geophysical consequences of plume involvement in the Emeishan flodd-basalt province. Geology, 32: 917–920
Xu Y G, Wei X, Luo Z Y, et al. 2014. The Early Permian Tarim Large Igneous Province: Main characteristics and a plume incubation model. Lithos, 240: 20–35
Yang J H, Wu FY, Wilde S A, et al. 2008. Mesozoic decratonization of the North China block. Geology, 36: 467–470
Yang Y H, Wu F Y, Wilde S A, et al. 2009. In-situ perovskite Sr-Nd isotopic constraints on the petrogenesis of the Ordovician Mengyin kimberlites in the North China Craton. Chem Geol, 264: 24–42
Yuen D A, Fleitout L. 1985. Thinning of the lithosphere by small-scale convective destabilizaion. Nature, 313: 125–128
Zandt G, Gilbert H, Owens T J, et al. 2004. Active foundering of a continental arc root beneath the Southern Sierra Nevada, California. Nature, 431: 41–46
Zhang J J, Zheng Y F, Zhao Z F. 2009. Geochemical evidence for interaction between oceanic crust and lithospheric mantle in the origin of Cenozoic continental basalts in east-central China. Lithos, 110: 305–326
Zhang Q. 2011. The evolution from “Lithospheric thinning” to “Cratonic destruction” (in Chinese with English abstract). Prog Geophys, 26: 2262–2269
Zhao G C, Cawood P A, Wilde S A. 2002. Review of global 2.1-1.8 Ga orogens: Implications for a pre-Rodinia supercontinent. Earth Sci Rev, 59: 125–162
Zhao G C, Sun, M, Wilde S A. 2003. Correlations between the Eastern Block of the North China Craton and the South Indian Block of the Indian Shield: An Archean to Paleoproterozoic link. Precambrian Res, 122: 201–233
Zheng J P. 1999. Mesozoic-Cenozoic Mantle Replacement and Lithospheric Thinning Beneath the Eastern China (in Chinese with English abstract). Wuhan: China Uni Geosci Press. 126
Zheng Y F, Wu F Y. 2009. Growth and reworking of cratonic lithosphere. Chin Sci Bull, 54: 3347–3353
Zhou X H. 2009. Major transformation of subcontinental lithosphere beneath North China in Cenozoic-Mesozoic: Revised (in Chinese with English abstract). Geol J China Uni, 15: 1–18
Zhu R X, Xu Y G, Zhu G, et al. 2012. Destruction of the North China Craton. Sci China Earth Sci, 55: 565–1587
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Wu, F., Xu, Y., Zhu, R. et al. Thinning and destruction of the cratonic lithosphere: A global perspective. Sci. China Earth Sci. 57, 2878–2890 (2014). https://doi.org/10.1007/s11430-014-4995-0
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DOI: https://doi.org/10.1007/s11430-014-4995-0