|
UTIG RESEARCH PROJECTS ARCHIVE
Structure of the Chicxulub KT Impact Crater,
Yucatan, Gulf of Mexico
 UTIG
scientists involved with the 1996 Chicxulub OBS program: Yosio Nakamura, Ben Yates, Gail
Christeson, Richard Buffler, John Brittan (from Imperial College).
Chicxulub Research Cruise Movie
Principal Investigators: Richard T. Buffler,
Gail Christeson, and Yosio Nakamura
Funded by: National Science Foundation
Imperial College Chicxulub homepage
Philippe Claeys' latest Chicxulub page
The Chicxulub structure occurs along the northern coast of the Yucatan peninsula in the
Gulf of Mexico. It is buried beneath up to a kilometer of Tertiary carbonates. Its upper
boundary has been drilled, and it has been mapped on the basis of potential field and
Landsat data. It is now widely believed that the Chicxulub structure represents a large
meteorite impact that was responsible for the mass extinctions at the Cretaceous-Tertiary
(KT) boundary.
The purpose of this joint project is to image in detail the internal crustal structure
and morphology of the Chicxulub impact crater and to quantify its dimensions. The project
involves the collection, processing and interpretation of a series of deep penetration
seismic reflection profiles, wide-angle seismic measurements, and refraction measurements
from the offshore portion of the crater. It represents a joint collaborative effort
between the British Institutions Reflection Profiling Syndicate (BIRPS)
(UK), the Canadian Geological Survey,
Imperial College (UK), the Lunar and Planetary Institute, the
Universidad Nacional Autónoma de México (UNAM), and The University of Texas Institute for Geophysics (UTIG).
UTIG deployed an array of OBS instruments along two key
lines. The OBS wide-angle and refraction data were collected at the same time as the
reflection data and are being integrated with the land-based wide-angle data to model the
velocity structure of the Chicxulub crater.
The OBS instruments were deployed from the UT-MSI RV Longhorn based out of Port
Aransas. Data were collected along lines totaling about 500 km. UTIG students and
technical support participated in the data acquisition along with UNAM and PEMEX
observers. Canadian Geological Survey personnel also were aboard to collect gravity and
magnetics data, and John Brittan from Imperial College helped coordinate activities with
the seismic reflection program.
Primary Objectives
- Constrain radial extent of impact structure.
- Determine position of the top, base and edges of the impact melt sheet and, hence, its
total volume.
- Constrain amount and style of deep basement uplift and its later extent.
- Measure thickness of the crust outside the region of the basement uplift and within the
crater itself.
- Determine the style of faulting and deformation on the flanks of the structure.
- Measure degree of radial asymmetry of the major structural and morphological elements
within the crater.
- Infer position and depth of transient crater, the depth of crustal excavation, and the
depth to which the lithosphere was fractured.
Broader Objectives
- Extend and improve the scaling laws for large impact events.
- Improve our understanding and models of ring formation for large impact basins.
- Improve our models and understanding of the process and extent of the central uplift.
- Quantify the amounts of potential environmental pollutants (dust, oxides of carbon,
sulfur, and nitrogen) released by the impact.
|
