• Title of article

    Dynamic modeling suggests terrace zone asymmetry in the Chicxulub crater is caused by target heterogeneity

  • Author/Authors

    Collins، نويسنده , , Gareth S. and Morgan، نويسنده , , Joanna and Barton، نويسنده , , Penny and Christeson، نويسنده , , Gail L. and Gulick، نويسنده , , Sean and Urrutia، نويسنده , , Jaime and Warner، نويسنده , , Michael and Wünnemann، نويسنده , , Kai، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2008
  • Pages
    10
  • From page
    221
  • To page
    230
  • Abstract
    We investigate the cause of terrace zone asymmetry in the Chicxulub impact crater using dynamic models of crater formation. Marine seismic data acquired across the crater show that the geometry of the craterʹs terrace zone, a series of sedimentary megablocks that slumped into the crater from the crater rim, varies significantly around the offshore half of the crater. The seismic data also reveal that, at the time of impact, both the water depth and sediment thickness varied with azimuth around the impact site. To test whether the observed heterogeneity in the pre-impact target might have affected terrace zone geometry we constructed two end-member models of upper-target structure at Chicxulub, based on the seismic data at different azimuths. One model, representing the northwest sector, had no water layer and a 3-km thick sediment layer; the other model, representing the northeast sector, had a 2-km water layer above a 4-km sediment layer. Numerical models of vertical impacts into these two targets produced final craters that differ substantially in terrace zone geometry, suggesting that the initial water depth and sediment thickness variations affected the structure of the terrace zone at Chicxulub. Moreover, the differences in terrace zone geometry between the two numerical models are consistent with the observed differences in the geometry of the terrace zone at different azimuths around the Chicxulub crater. We conclude that asymmetry in the pre-impact target rocks at Chicxulub is likely to be the primary cause of asymmetry in the terrace zone.
  • Keywords
    Chicxulub , crater asymmetry , Dynamic modeling , Impact angle
  • Journal title
    Earth and Planetary Science Letters
  • Serial Year
    2008
  • Journal title
    Earth and Planetary Science Letters
  • Record number

    2326832