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  • GSA (Geological Society of America)  (2)
  • Springer  (1)
  • 1
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    The continental geotherm and the evolution of rifted margins (2004)
    GSA (Geological Society of America)
    In:  Geology, 32 (2). pp. 133-136.
    Details
    Publication Date: 2019-10-24
    Description: Models of melting accompanying mantle upwelling predict far more melt than is observed at nonvolcanic margins. The discrepancy may be explained if the paradigm of a uniform asthenosphere is incorrect. Work on the velocity structure of the continents has shown that the convecting sublithospheric mantle may have a potential temperature as low as 1200 °C, ∼100 °C cooler than that beneath the oceans. The continental geotherm derived from studies on xenoliths brought up by kimberlites is also compatible with a cool sublithospheric mantle except where perturbed by mantle plumes. Upwelling of such cool mantle during rifting leads to little melt production, even for rapid extension rates, explaining the formation of amagmatic margins away from mantle plumes. However, the transition to seafloor spreading and the development of normal-thickness oceanic crust requires the invasion of the amagmatic rift by hotter oceanic asthenosphere and/or plume material. This influx may cause a transient thermal uplift, recorded as a breakup unconformity. Conversely, at volcanic margins, the onset of seafloor spreading is accompanied by the escape of the hot plume puddle along the mid-ocean ridge system away from the volcanic margin, leading to a pulse of rapid subsidence.
    Type: Article , PeerReviewed
    Format: text
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  • 2
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    Lithospheric extension from rifting to continental breakup at magma-poor margins: rheology, serpentinisation and symmetry (2007)
    Springer
    In:  International Journal of Earth Sciences, 96 (6). pp. 1033-1046.
    Details
    Publication Date: 2017-05-18
    Description: The symmetry or asymmetry of the process of continental breakup has been much debated over the last 20 years, with various authors proposing asymmetric simple shear models, others advocating more symmetric, pure shear models and some combinations of the two. The unroofing of vast expanses of sub-continental mantle at non-volcanic margins has led some authors to argue in favour of simple shear models, but supporting evidence is lacking. Subsidence evidence from conjugate margin pairs is equivocal, and the detailed crustal and lithospheric structure of such pairs not generally well enough known to draw firm conclusions. In the Porcupine Basin, where the final stages of break-up are preserved, the development of structural asymmetry is demonstrable, and apparently related to late stage coupling of the crust to the mantle following the complete embrittlement of the crust. This agrees with theoretical modelling results, which predict that asymmetric models can develop only on a lithospheric scale when the crust and mantle are tightly coupled. However, whether such asymmetry is maintained during continued exhumation of the mantle is unclear.
    Type: Article , PeerReviewed
    Format: text
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  • 3
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    The extension discrepancy at North Atlantic non-volcanic rifted margins: depth-dependent stretching or unrecognised faulting? (2007)
    GSA (Geological Society of America)
    In:  Geology, 35 . pp. 367-370.
    Details
    Publication Date: 2019-10-24
    Description: Rifted margins show an apparent discrepancy between the amount of extension measurable from faults and the amount of crustal or lithospheric thinning determined from wide-angle data or subsidence. This extension discrepancy has been interpreted in terms of depth-dependent stretching in which the upper crust is extended and thinned far less than the rest of the lithosphere. Here I show that at those nonvolcanic margins where the velocity structure is well known, the upper and lower crust appear to thin equally toward the margin, implying that the discrepancy is not due to depth-dependent stretching, but more likely due to unrecognized polyphase and top basement faulting.
    Type: Article , PeerReviewed
    Format: text
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