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“Historic Impact Craters”. Earth2Class Workshops for Teachers Lamont-Doherty Earth Observatory Originally presented 7 May 2005. Guest Scientist. Dr. Dallas Abbott Visiting Assistant Professor, Barnard College and LDEO Research Scientist dallas@ldeo.columbia.edu .
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“Historic Impact Craters” Earth2Class Workshops for Teachers Lamont-Doherty Earth Observatory Originally presented 7 May 2005
Guest Scientist Dr. Dallas Abbott Visiting Assistant Professor, Barnard College and LDEO Research Scientist dallas@ldeo.columbia.edu
Recent research has led Dr. Abbott to investigate data from sea floor studies that may be the result of impacts of asteroids, meteorites, and other extraterrestrial objects. She will provide more evidence from petrologic studies and other techniques during her portion of this program.
Impact craters on land have been known and studied for many years. This STS-9 image of The Manicouagan Crater in northern Canada shows the remains of a collision estimated to have taken place 200 million years ago. http://antwrp.gsfc.nasa.gov/apod/ap001213.html
One of the best presentations about impact craters on the Internet is Terrestrial Impact Craters, Second EditionCompiled by Christian Koeberland Virgil L. SharptonThey include descriptions and images from craters on Earth and elsewhere in the solar system http://cass.jsc.nasa.gov/publications/slidesets/craters.html
Some important concepts about impact craters • Form when a meteoroid (asteroid or comet) collides with a solid planet or moon • Clearly seen on the Moon, Mercury, and Mars, where weathering and erosion are slow • Often hard to recognize on Earth because of the effects of weathering and erosion
Meteor Crater (Barringer Crater) in Arizona was the first recognized http://cass.jsc.nasa.gov/images/scraters/scraters_S10.gif
Many other craters have subsequently been identified, especially by remote sensing • Earth’s greater gravitation pull probably means it has been hit more, but water, atmospheric weathering, and plate tectonicshave destroyed or hidden many impact sites • Approximately 160 are known • Mostly within the stable cratons of North America, Africa, Australia, and Europe
http://cass.jsc.nasa.gov/publications/slidesets/craters.html
High velocities at which meteoroids collide with Earth explain the great effects from even small objects • Velocities range between 11.2 km/sec (escape velocity from Earth) and 72 km/sec (orbital velocity of Earth plus escape velocity of solar system) • Kinetic Energy released is proportional to square of velocity • Effects is that meteorites are, gram for gram, more than 100x as powerful as TNT!
Impact Craters are classified as “Simple” or “Complex” • “Simple Craters” are relatively small, have a smooth bowl shape, and a depth:diameter ratio of 1:5 to 1:7 • “Complex Craters” are largely and show the effect of gravitational collapse of the walls to produce a central peak or peak ring • These are illustrated in the next slide
http://cass.jsc.nasa.gov/publications/slidesets/craters.html
Many craters or remnants have been recognized by the presence of rare elements • “Siderophile elements” such as Ir indicate that terrestrial clays have been mixed with extraterrestrial materials • One of the best studied is the subsurface Chicxulub structure in Mexico, widely accepted at the location of the Cretaceous-Tertiary boundary event
Not exposed at the surface, it has been identified through geophysical studies of the gravitational field. Located at 21.3°N 89.6°W, the structure has a diameter of ~250-280 km. Its age has been calculated at 64.98 ± 0.05 million years http://cass.jsc.nasa.gov/images/scraters/scraters_S37.gif
Connections between impacts and mass extinctions provide evidence for the still-unproved theory that such events may be the “metronome that sets the cadence for biological evolution on Earth.” (Koeberl and Sharpton)
Methods to identify impact locations include: • Siderophile elements (esp. Ir, Os, and Pt) in “impact melt rocks” • “Shock metamorphism” in “target rocks” and minerals • “Shatter cones” • High-pressure mineral phases, such as stishovite • “Diaplectic glass” and tektites in “ejecta blankets”
What might happen when an impact occurs in the ocean? Tsunami! • A tsunami, as we all now know much better than a year ago, is a giant sea wave or series of waves caused by disruption of the ocean surface • Tsunamis are sometimes erroneously called “tidal wave,” but have nothing to do with tidal motions • Most tsunamis are connected with earthquakes or volcanic eruptions • For more information about tsunamis, go to http://www.geophys.washington.edu/tsunami/welcome.html
But considering the force with which an impact occurs, could it trigger a tsunami? • What evidence would still exist of past events? • Does such evidence actually exist?
NASA’s Jet Propulsion Laboratory provides much more information about impact craters throughout the solar system in their “Welcome to the Planets” web sitehttp://pds.jpl.nasa.gov/planets/
Excellent information and classroom activities have been created by the Hawai'i Space Grant College, Hawai'i Institute of Geophysics and Planetology, University of Hawai'i http://www.spacegrant.hawaii.edu/class_acts/CrateringDoc.html
Selected URLs about Impact Craters • For more information and some classroom activities: • http://www.solarviews.com/eng/edu/craters.htm • The Meteor Crater home page: http://www.meteorcrater.com/ • A Webquest about impact craters: http://earthview.sdsu.edu/trees/impact.html
New Zealand Hazard Watch In last year’s talk, Dr. Abbott presented an interesting description of her research about impact craters. The focus of her research lies in New Zealand, an island nation that experiences a wide variety of natural hazards. Government web sites monitor, in addition to tsunamis, such events as volcanoes (which created the two islands); earthquakes, floods, landslides, and other hazards. http://www.gns.cri.nz/hazardwatch/latest/index.html
In this year’s talk, Dr. Abbott shares information about her most recent research about impact craters. Her willingness to interact each spring with E2C teachers exemplifies what this program can provide for both researchers and educators.