Rapid transition from continental breakup to igneous oceanic crust in the South China Sea

H. C. Larsen; G. Mohn; M. Nirrengarten; Z. Sun; J. Stock; Z. Jian; A. Klaus; C. A. Alvarez-Zarikian; J. Boaga; S. A. Bowden; A. Briais; Y. Chen; D. Cukur; K. Dadd; W. Ding; M. Dorais; E. C. Ferré; F. Ferreira; A. Furusawa; A. Gewecke; J. Hinojosa; T. W. Höfig; K. H. Hsiung; B. Huang; E. Huang; X. L. Huang; S. Jiang; H. Jin; B. G. Johnson; R. M. Kurzawski; C. Lei; B. Li; L. Li; Y. Li; J. Lin; C. Liu; C. Liu; Z. Liu; A. J. Luna; C. Lupi; A. McCarthy; L. Ningthoujam; N. Osono; D. W. Peate; P. Persaud; N. Qiu; C. Robinson; S. Satolli; I. Sauermilch; J. C. Schindlbeck; S. Skinner; S. Straub; X. Su; C. Su; L. Tian; F. M. van der Zwan; S. Wan; H. Wu; R. Xiang; R. Yadav; L. Yi; P. S. Yu; C. Zhang; J. Zhang; Y. Zhang; N. Zhao; G. Zhong; L. Zhong

doi:10.1038/s41561-018-0198-1

Rapid transition from continental breakup to igneous oceanic crust in the South China Sea

H. C. Larsen^*
, G. Mohn
, M. Nirrengarten
, Z. Sun
, J. Stock
, Z. Jian
, A. Klaus
, C. A. Alvarez-Zarikian
, J. Boaga
, S. A. Bowden
, A. Briais
, Y. Chen
, D. Cukur
, K. Dadd
, W. Ding
, M. Dorais
, E. C. Ferré
, F. Ferreira
, A. Furusawa
, A. Gewecke

J. Hinojosa, T. W. Höfig, K. H. Hsiung, B. Huang, E. Huang, X. L. Huang, S. Jiang, H. Jin, B. G. Johnson, R. M. Kurzawski, C. Lei, B. Li, L. Li, Y. Li, J. Lin, C. Liu, C. Liu, Z. Liu, A. J. Luna, C. Lupi, A. McCarthy, L. Ningthoujam, N. Osono, D. W. Peate, P. Persaud, N. Qiu, C. Robinson, S. Satolli, I. Sauermilch, J. C. Schindlbeck, S. Skinner, S. Straub, X. Su, C. Su, L. Tian, F. M. van der Zwan, S. Wan, H. Wu, R. Xiang, R. Yadav, L. Yi, P. S. Yu, C. Zhang, J. Zhang, Y. Zhang, N. Zhao, G. Zhong, L. Zhong

^*Corresponding author for this work

Tongji University
Geological Survey of Denmark and Greenland
CY Cergy Paris Université
CAS - South China Sea Institute of Oceanology
California Institute of Technology
Texas A&M University
University of Padua
University of Aberdeen
Université P. Sabatier
CAS - Guangzhou Institute of Geochemistry
Korea Institute of Geoscience and Mineral Resources
University of Sydney
Ministry of Natural Resources of the People's Republic of China
Brigham Young University
University of Louisiana at Lafayette
Universidade Federal Fluminense
Shimane University
University of Nebraska-Lincoln
Japan Agency for Marine-Earth Science and Technology
Peking University
Jinan University
West Virginia University
Helmholtz Centre for Ocean Research Kiel
Kiel University
China University of Geosciences, Wuhan
CAS - Nanjing Institute of Geology and Palaeontology
Nanjing University
Woods Hole Oceanographic Institution
Louisiana State University
University of South Florida
University of Pavia
University of Lausanne
University of Bristol
National Centre for Antarctic & Ocean Research
Graduate School of Science and Technology for Innovation
University of Iowa
Ohio State University
Gabriele d'Annunzio University
University of Tasmania
Heidelberg University
California State University Sacramento
Columbia University
National Taiwan University
Chinese Academy of Sciences
CAS - Institute of Oceanology
China University of Geosciences, Beijing
Taiwan Ocean Research Institute
Purdue University
Sun Yat-Sen University

Research output: Contribution to journal › Article › peer-review

283 Scopus citations

Abstract

Continental breakup represents the successful process of rifting and thinning of the continental lithosphere, leading to plate rupture and initiation of oceanic crust formation. Magmatism during breakup seems to follow a path of either excessive, transient magmatism (magma-rich margins) or of igneous starvation (magma-poor margins). The latter type is characterized by extreme continental lithospheric extension and mantle exhumation prior to igneous oceanic crust formation. Discovery of magma-poor margins has raised fundamental questions about the onset of ocean-floor type magmatism, and has guided interpretation of seismic data across many rifted margins, including the highly extended northern South China Sea margin. Here we report International Ocean Discovery Program drilling data from the northern South China Sea margin, testing the magma-poor margin model outside the North Atlantic. Contrary to expectations, results show initiation of Mid-Ocean Ridge basalt type magmatism during breakup, with a narrow and rapid transition into igneous oceanic crust. Coring and seismic data suggest that fast lithospheric extension without mantle exhumation generated a margin structure between the two endmembers. Asthenospheric upwelling yielding Mid-Ocean Ridge basalt-type magmatism from normal-temperature mantle during final breakup is interpreted to reflect rapid rifting within thin pre-rift lithosphere.

Original language	English
Pages (from-to)	782-789
Number of pages	8
Journal	Nature Geoscience
Volume	11
Issue number	10
DOIs	https://doi.org/10.1038/s41561-018-0198-1
State	Published - 1 Oct 2018
Externally published	Yes

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Larsen, H. C., Mohn, G., Nirrengarten, M., Sun, Z., Stock, J., Jian, Z., Klaus, A., Alvarez-Zarikian, C. A., Boaga, J., Bowden, S. A., Briais, A., Chen, Y., Cukur, D., Dadd, K., Ding, W., Dorais, M., Ferré, E. C., Ferreira, F., Furusawa, A., ... Zhong, L. (2018). Rapid transition from continental breakup to igneous oceanic crust in the South China Sea. Nature Geoscience, 11(10), 782-789. https://doi.org/10.1038/s41561-018-0198-1

@article{fff51f31f0214bd38fe75af9621cea6e,

title = "Rapid transition from continental breakup to igneous oceanic crust in the South China Sea",

abstract = "Continental breakup represents the successful process of rifting and thinning of the continental lithosphere, leading to plate rupture and initiation of oceanic crust formation. Magmatism during breakup seems to follow a path of either excessive, transient magmatism (magma-rich margins) or of igneous starvation (magma-poor margins). The latter type is characterized by extreme continental lithospheric extension and mantle exhumation prior to igneous oceanic crust formation. Discovery of magma-poor margins has raised fundamental questions about the onset of ocean-floor type magmatism, and has guided interpretation of seismic data across many rifted margins, including the highly extended northern South China Sea margin. Here we report International Ocean Discovery Program drilling data from the northern South China Sea margin, testing the magma-poor margin model outside the North Atlantic. Contrary to expectations, results show initiation of Mid-Ocean Ridge basalt type magmatism during breakup, with a narrow and rapid transition into igneous oceanic crust. Coring and seismic data suggest that fast lithospheric extension without mantle exhumation generated a margin structure between the two endmembers. Asthenospheric upwelling yielding Mid-Ocean Ridge basalt-type magmatism from normal-temperature mantle during final breakup is interpreted to reflect rapid rifting within thin pre-rift lithosphere.",

author = "Larsen, \{H. C.\} and G. Mohn and M. Nirrengarten and Z. Sun and J. Stock and Z. Jian and A. Klaus and Alvarez-Zarikian, \{C. A.\} and J. Boaga and Bowden, \{S. A.\} and A. Briais and Y. Chen and D. Cukur and K. Dadd and W. Ding and M. Dorais and Ferr{\'e}, \{E. C.\} and F. Ferreira and A. Furusawa and A. Gewecke and J. Hinojosa and H{\"o}fig, \{T. W.\} and Hsiung, \{K. H.\} and B. Huang and E. Huang and Huang, \{X. L.\} and S. Jiang and H. Jin and Johnson, \{B. G.\} and Kurzawski, \{R. M.\} and C. Lei and B. Li and L. Li and Y. Li and J. Lin and C. Liu and C. Liu and Z. Liu and Luna, \{A. J.\} and C. Lupi and A. McCarthy and L. Ningthoujam and N. Osono and Peate, \{D. W.\} and P. Persaud and N. Qiu and C. Robinson and S. Satolli and I. Sauermilch and Schindlbeck, \{J. C.\} and S. Skinner and S. Straub and X. Su and C. Su and L. Tian and \{van der Zwan\}, \{F. M.\} and S. Wan and H. Wu and R. Xiang and R. Yadav and L. Yi and Yu, \{P. S.\} and C. Zhang and J. Zhang and Y. Zhang and N. Zhao and G. Zhong and L. Zhong",

note = "Publisher Copyright: {\textcopyright} 2018, The Author(s).",

year = "2018",

month = oct,

day = "1",

doi = "10.1038/s41561-018-0198-1",

language = "英语",

volume = "11",

pages = "782--789",

journal = "Nature Geoscience",

issn = "1752-0894",

publisher = "Nature Publishing Group",

number = "10",

}

Larsen, HC, Mohn, G, Nirrengarten, M, Sun, Z, Stock, J, Jian, Z, Klaus, A, Alvarez-Zarikian, CA, Boaga, J, Bowden, SA, Briais, A, Chen, Y, Cukur, D, Dadd, K, Ding, W, Dorais, M, Ferré, EC, Ferreira, F, Furusawa, A, Gewecke, A, Hinojosa, J, Höfig, TW, Hsiung, KH, Huang, B, Huang, E, Huang, XL, Jiang, S, Jin, H, Johnson, BG, Kurzawski, RM, Lei, C, Li, B, Li, L, Li, Y, Lin, J, Liu, C, Liu, C, Liu, Z, Luna, AJ, Lupi, C, McCarthy, A, Ningthoujam, L, Osono, N, Peate, DW, Persaud, P, Qiu, N, Robinson, C, Satolli, S, Sauermilch, I, Schindlbeck, JC, Skinner, S, Straub, S, Su, X, Su, C, Tian, L, van der Zwan, FM, Wan, S, Wu, H, Xiang, R, Yadav, R, Yi, L, Yu, PS, Zhang, C, Zhang, J, Zhang, Y, Zhao, N, Zhong, G & Zhong, L 2018, 'Rapid transition from continental breakup to igneous oceanic crust in the South China Sea', Nature Geoscience, vol. 11, no. 10, pp. 782-789. https://doi.org/10.1038/s41561-018-0198-1

TY - JOUR

T1 - Rapid transition from continental breakup to igneous oceanic crust in the South China Sea

AU - Larsen, H. C.

AU - Mohn, G.

AU - Nirrengarten, M.

AU - Sun, Z.

AU - Stock, J.

AU - Jian, Z.

AU - Klaus, A.

AU - Alvarez-Zarikian, C. A.

AU - Boaga, J.

AU - Bowden, S. A.

AU - Briais, A.

AU - Chen, Y.

AU - Cukur, D.

AU - Dadd, K.

AU - Ding, W.

AU - Dorais, M.

AU - Ferré, E. C.

AU - Ferreira, F.

AU - Furusawa, A.

AU - Gewecke, A.

AU - Hinojosa, J.

AU - Höfig, T. W.

AU - Hsiung, K. H.

AU - Huang, B.

AU - Huang, E.

AU - Huang, X. L.

AU - Jiang, S.

AU - Jin, H.

AU - Johnson, B. G.

AU - Kurzawski, R. M.

AU - Lei, C.

AU - Li, B.

AU - Li, L.

AU - Li, Y.

AU - Lin, J.

AU - Liu, C.

AU - Liu, Z.

AU - Luna, A. J.

AU - Lupi, C.

AU - McCarthy, A.

AU - Ningthoujam, L.

AU - Osono, N.

AU - Peate, D. W.

AU - Persaud, P.

AU - Qiu, N.

AU - Robinson, C.

AU - Satolli, S.

AU - Sauermilch, I.

AU - Schindlbeck, J. C.

AU - Skinner, S.

AU - Straub, S.

AU - Su, X.

AU - Su, C.

AU - Tian, L.

AU - van der Zwan, F. M.

AU - Wan, S.

AU - Wu, H.

AU - Xiang, R.

AU - Yadav, R.

AU - Yi, L.

AU - Yu, P. S.

AU - Zhang, C.

AU - Zhang, J.

AU - Zhang, Y.

AU - Zhao, N.

AU - Zhong, G.

AU - Zhong, L.

PY - 2018/10/1

Y1 - 2018/10/1

N2 - Continental breakup represents the successful process of rifting and thinning of the continental lithosphere, leading to plate rupture and initiation of oceanic crust formation. Magmatism during breakup seems to follow a path of either excessive, transient magmatism (magma-rich margins) or of igneous starvation (magma-poor margins). The latter type is characterized by extreme continental lithospheric extension and mantle exhumation prior to igneous oceanic crust formation. Discovery of magma-poor margins has raised fundamental questions about the onset of ocean-floor type magmatism, and has guided interpretation of seismic data across many rifted margins, including the highly extended northern South China Sea margin. Here we report International Ocean Discovery Program drilling data from the northern South China Sea margin, testing the magma-poor margin model outside the North Atlantic. Contrary to expectations, results show initiation of Mid-Ocean Ridge basalt type magmatism during breakup, with a narrow and rapid transition into igneous oceanic crust. Coring and seismic data suggest that fast lithospheric extension without mantle exhumation generated a margin structure between the two endmembers. Asthenospheric upwelling yielding Mid-Ocean Ridge basalt-type magmatism from normal-temperature mantle during final breakup is interpreted to reflect rapid rifting within thin pre-rift lithosphere.

AB - Continental breakup represents the successful process of rifting and thinning of the continental lithosphere, leading to plate rupture and initiation of oceanic crust formation. Magmatism during breakup seems to follow a path of either excessive, transient magmatism (magma-rich margins) or of igneous starvation (magma-poor margins). The latter type is characterized by extreme continental lithospheric extension and mantle exhumation prior to igneous oceanic crust formation. Discovery of magma-poor margins has raised fundamental questions about the onset of ocean-floor type magmatism, and has guided interpretation of seismic data across many rifted margins, including the highly extended northern South China Sea margin. Here we report International Ocean Discovery Program drilling data from the northern South China Sea margin, testing the magma-poor margin model outside the North Atlantic. Contrary to expectations, results show initiation of Mid-Ocean Ridge basalt type magmatism during breakup, with a narrow and rapid transition into igneous oceanic crust. Coring and seismic data suggest that fast lithospheric extension without mantle exhumation generated a margin structure between the two endmembers. Asthenospheric upwelling yielding Mid-Ocean Ridge basalt-type magmatism from normal-temperature mantle during final breakup is interpreted to reflect rapid rifting within thin pre-rift lithosphere.

UR - https://www.scopus.com/pages/publications/85052607700

U2 - 10.1038/s41561-018-0198-1

DO - 10.1038/s41561-018-0198-1

M3 - 文章

AN - SCOPUS:85052607700

SN - 1752-0894

VL - 11

SP - 782

EP - 789

JO - Nature Geoscience

JF - Nature Geoscience

IS - 10

ER -

Rapid transition from continental breakup to igneous oceanic crust in the South China Sea

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