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_EARTH'S HISTORY_

Chicxulub Impact Crater Provides Clues to Earth's History
_______________________

_Earth in Space Vol. 8, No. 4, December 1995, p. 7. © 1995 American
Geophysical Union._ Permission is hereby granted to journalists to use
this material so long as credit is given, and to teachers to use this
material in classrooms.
_________________________________________________________________

An extraterrestrial impact 65 million years ago changed the course of
life on Earth. The crater it carved in the Earth's surface could now
help scientists study past global change.

by Virgil L. Sharpton, Lunar and Planetary Institute, Houston, Texas

In 1980, Luis Alvarez and his geologist son, Walter, proposed that a
giant asteroid or comet struck the Earth approximately 65 million
years ago and caused the mass extinctions of the dinosaurs and over
70% of all life on Earth. This bold proposition resulted from their
discovery, near the Medieval town of Gubbio, Italy, of a
centimeter-thick clay layer among limestones deposited on the Earth's
surface at the time of the extinction event, between two geologic time
intervals, the _[1]Cretaceous_ (K) and _[2]Tertiary_ (T). The
limestone directly beneath the clay layer abounds with _[3]planktic
formaniferids_ of latest Cretaceous age, while the Tertiary limestone
unit immediately above the clay layer showed only rare and poorly
formed fossils. Thus the clay layer itself, the scientists reasoned,
must hold clues to the duration and nature of the mysterious KT
extinction event, one of the most dramatic calamities to afflict
Earth's biosphere since the development of complex life over a billion
years ago. They found that the clay contained high concentrations of
the element iridium, extremely rare in Earth's crustal rocks but quite
abundant in certain meteorites, and proposed that this clay was the
altered remains of the dust cloud blasted around the world when a
10-km-wide asteroid or comet struck the Earth. Fifteen years of
research has upheld this idea, and, now, all indications are that the
source crater has been found.

The collision occurred on the Yucatán platform and is centered near
the port city of Progreso, Mexico. The 200-300-kilometer wide crater
lies buried beneath 1100 meters of limestone laid down in the
intervening years and few clues of its presence remain at the surface.
Yet prominent circular _[4]anomalies_ in geophysical data gained the
interest of Petroleos Mexicanos and in the early 1950s, they began an
exploration campaign that included deep drilling to recover samples of
the subsurface rocks. The buried feature became known as the Chicxulub
structure (see [5]figure 1), named for the first well located near the
Mayan village by the same name. Pemex drilling continued throughout
the early 1970s, and by that time, Mexican scientists realized that
the Chicxulub structure was quite unusual. Three wells near the center
had recovered silicate rocks with igneous textures, initially mistaken
for volcanic rocks, and others, located between 140 km and 210 km from
ground zero recovered breccia deposits hundreds of meters thick,
indicating catastrophic or explosive conditions. By 1980, at least one
scientist at Pemex felt that the evidence pointed to impact, although
a volcanic origin for the Chicxulub structure could not be ruled out.

_Fig.1._ _Surface geology, ring locations from gravity data, and wells
near the Chicxulub impact basin. The three wells that penetrated
impact melt rocks and breccias beneath the carbonate cover rocks are
C1 (Chicxulub 1), S1 (Sacapuc 1), and Y6 (Yucatan 6). Other well sites
shown are Yucatan 1 (Y1), Yucatan 2 (Y2), Yucatan 5A (Y5A), and Ticul
1 (T1). The Yucatan 4 (Y4) well site is located off the map, ~65 km
east of Y5A. Carbonate units at the surface are Q (Quaternary; <2 Ma),
Tu (Upper Tertiary; ~2-35 Ma), To (Oligocene; ~25-35 Ma),Te (Eocene;
~35-55 Ma), and Tpal (Paleocene; ~55-65.0 Ma). The crater center is
indicated by ×. Hatchured lines represent the Ticul fault system.
Dashed lines indicate trend of ringlike zone of water-filled
sinkholes. _

Beginning in 1990, however, samples from the Pemex wells were located
in Mexico City and teams of scientists from the United States and
Mexico quickly developed an impressive case that the Chicxulub
structure was indeed the KT "smoking gun." Mineral evidence of shock
metamorphism, requiring pressures and strain rates considerably higher
than those produced by terrestrial processes, indicated that the
crystalline rocks within the basin were melt rocks formed by an impact
event and not by volcanism. _[6]Biostratigraphic_ information
indicates that the structure was formed in uppermost Cretaceous rocks,
consistent with a KT age. Argon and uranium-lead age determinations
reveal that the melt rocks and the associated breccias are the same
age as the tiny _[7]spherules_ of impact glass found within KT
boundary deposits in Haiti and Mexico and the unmelted granitic
fragments found in KT boundary exposures throughout western North
America. Isotopic analyses demonstrate that the Chicxulub melt rocks
and the ejecta spherules originated from the same source rocks.
Consequently, there is a clear chemical as well as temporal link
between the Chicxulub structure and the KT boundary deposits.

Additional geological and geophysical evidence collected over the last
few years now suggests that Chicxulub could be the largest impact
basin to form on Earth in the last billion years or so. Over 200
thousand cubic kilometers of the Earth's crust was instantly
vaporized, melted or ejected from the crater. Studies of this
structure through additional scientific drill coring and seismic
profiling will shed valuable new light on understanding the cratering
process and its geological implications. Perhaps less clear but of
more immediate concern is what additional studies of the Chicxulub
basin-forming event could provide for research into modern global
climate change. Concerns over global warming and acid rain production
induced by human activities prompt important questions about the
future health and economic security of the world's population. Experts
readily admit, however, that modern climate change research is
chock-full of uncertainties about how the Earth responds to the rapid
and dramatic changes imposed by human activities. These uncertainties
adversely affect predictions of sea level rise and changing climate
patterns and impede the formulation of effective international climate
change policies.

The KT impact event provides a case completely played out in the rock
record where a localized geological process--the collision of large
piece of space debris--induced a global environmental collapse
culminating in biological devastation. Yet, much is not understood at
present about how such an impact event could have changed the
environment, but adverse changes in the composition of the atmosphere
are strongly implied. The uppermost 2-3 kilometers of rocks involved
in the Chicxulub collision are composed of calcium carbonate
(limestone) and calcium sulfate (anhydrite). When such rocks are
heated under the extreme temperatures of high-speed impact, the
greenhouse gas carbon dioxide and sulfate aerosols, which both
contribute to acid rain and smog, are released into the atmosphere.
Thus in addition to the dust and ash that could interfere with
sunlight reaching Earth's surface, the Chicxulub impact event probably
changed the global atmospheric composition in ways not unlike those
that result from modern human activities. By studying the record in
the rocks at Chicxulub, the magnitude of the crisis and the Earth's
response can be reconstructed. A better understanding of how Earth's
complex system of atmospheric, hydrologic, and geologic processes
reacted under the KT environmental crisis 65 million years ago might
help the contemporary global change community forecast and develop
remediation policies.

Source: _Eos_, Vol. 76, December 26, 1995.

GLOSSARY

_Anomalies _
Deviations from the common or normal type

_Biostratigraphic _
Pertaining to layers of the Earth identified by particular
fossil content

_Cretaceous_
The span of time between 135 and 65 million years ago

_Planktic formaniferids_
Tiny shelled sea creatures

_Spherules_
Little spheres or spherical bodies

_Tertiary_
The span of time between 65 and 3 to 2 million years ago
_________________________________________________________________

Suggested Reading

Alvarez, L. W., W. Alvarez, F. Asaro, and H. V. Michel,
Extraterrestrial cause for the Cretaceous/Tertiary extinction,
_Science, 208_, pages 1095-1008, 1980.

Dressler, B. O., R. A. F. Grieve, and V. L. Sharpton, (Eds.), Large
meteorite impacts and planetary evolution, _Geological Society of
America Special Paper 293_, 348 pp., 1994.

French, B. M., and N. M. Short, editors, _Shock Metamorphism of
Natural Materials_, Mono Book Corp., Baltimore, Md., 644 pp., 1968.

Grieve, R. A. F., Terrestrial Impact Structures, _Annual Reviews of
Earth and Planetary Science, 15_, pp. 245-270, 1987.

Melosh, H. J., _Impact Cratering: A Geological Process_, Oxford
University Press, New York, 245 pp., 1989.

Roddy, D. J., R. O. Pepin, and R. B. Merrill, (Eds.), _Impact and
Explosion Cratering_, Pergamon Press, New York, 1301 pp., 1977.

Sharpton, V. L., and P. D. Ward, editors, Global catastrophes in Earth
history, _Geological Society of America Special Paper 247_, 631 pp.,
1990.

Sharpton, V. L., G. B. Dalrymple, L. E. Marín, G. Ryder, B. C.
Schuraytz, and J. Urrutia-Fucugauchi, New links between the Chicxulub
impact structure and the Cretaceous/Tertiary boundary, _Nature, 359_,
819-821, 1992.

Sharpton, V. L., et al., Chicxulub Multiring Impact Basin: Size and
other characteristics derived from gravity analysis, _Science, 261_,
pp. 1564-1567, 1993.

Silver, L. T., and P. H. Schultz, editors, Geological implications of
impacts of large asteroids and comets on the Earth, _Geological
Society of America Special Paper 190_, 128 pp., 1982.