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Chicxulub Structure: A Volcanic Sequence of Late Cretaceous Age

Published online by Cambridge University Press:  26 July 2017

Charles B. Officer
Charles B. Officer*
Affiliation:
Earth Sciences Department, Dartmouth College, Hanover, New Hampshire 03755
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The present Cretaceous/Tertiary extinction debate started with findings by Alvarez et al. (1980) of enhanced levels of iridium at K/T sections in Italy, Denmark and New Zealand. They postulated that the iridium was extraterrestrial in origin and related to a 10 km diameter asteroid impact which would have produced a crater some 200 km in diameter. They further suggested that a giant dust cloud would have been injected into the stratosphere from the impact with a residence time of several years and that the resulting darkness would have suppressed photosynthesis with a consequent elimination of succeeding members in the biological food chain — ergo, a mass extinction event.

Type
Extinctions
Information
The Paleontological Society Special Publications , Volume 7: Dino Fest , 1994 , pp. 425 - 436
Copyright
Copyright © 1994 Paleontological Society 

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References

Alvarez, L.W., Alvarez, W., Asaro, F., and Michel, H.V. 1980. Extraterrestrial cause for the Cretaceous/Tertiary extinction. Science, 208:10951108.Google Scholar
Alvarez, W., et al. 1992. Proximal impact deposits at the Cretaceous-Tertiary boundary in the Gulf of Mexico: a restudy of DSDP Leg 77, Sites 536 and 540. Geology, 20:697700.Google Scholar
Bohor, B.F., and Seitz, R. 1990. Cuban K/T catastrophy. Nature, 344: 593.Google Scholar
Buffler, R.T., et al. 1984. Sites 535, 539 and 540. Initial Reports of the Deep Sea Drilling Project, 77:25217.Google Scholar
Carter, N.L. 1968. Dynamic deformation of quartz, p. 453474. In French, B.M. and Short, N.M. (eds.), Shock Metamorphism of Natural Materials, Mono Book, Baltimore.Google Scholar
Carter, N.L., Officer, C.B. and Drake, C.L. 1990. Dynamic deformation of quartz and feldspars: clues to causes of some natural crises. Tectonophysics, 171:373391.Google Scholar
Dietz, R.S. and McHone, J. 1990. Isle of Pines (Cuba), apparently not K/T boundary impact site. Geological Society of America Abstracts, 22, 7:A79.Google Scholar
Felitsyn, S.B. and Vaganov, P.A. 1988. Iridium in the ash of Kamchatkan volcanoes. International Geology Review, 30:12881291.Google Scholar
Heard, H.C. and Carter, N.L. 1968. Experimentally induced natural intragranular growth in quartz and quartzite. American Journal of Science, 266:142.Google Scholar
Hildebrand, A.R. and Boynton, W. 1990. Proximal Cretaceous-Tertiary impact deposits. Science, 248:843847.Google Scholar
Hildebrand, A.R. and Boynton, W. et al. 1991. Chicxulub crater: a possible Cretaceous/Tertiary boundary impact crater on the Yucatán Peninsula, Mexico. Geology, 19:867871.Google Scholar
Iturralde-Vinent, M.A. 1992. A short note on the Cuban late Maastrichtian megaturbidite (an impact-derived deposit?). Earth and Planetary Science Letters, 109:225228.Google Scholar
Izett, G.A., Cobban, W.A., Obradovich, J.D. and Kunk, M.J. 1993. The Manson impact structure: 40Ar/39Ar age and its distal ejecta in the Pierre Shale in southeastern South Dakota. Science, 262:729732.Google Scholar
Jéhanno, C. et al. 1992. The Cretaceous-Tertiary boundary at Beloc, Haiti: no evidence for an impact in the Caribbean area. Earth and Planetary Science Letters, 109:229241.Google Scholar
Keller, G., MacLeod, N., Lyons, J.B. and Officer, C.B. 1993. No evidence for Cretaceous-Tertiary boundary-age deep water deposits in the Caribbean and Gulf of Mexico. Geology, 21:776780.Google Scholar
Kent, D.V. 1981. Asteroid extinction hypothesis. Science, 211:649650.Google Scholar
Koeberl, C. 1989. Iridium enrichment in volcanic dust from blue ice fields, Antarctica, and possible relevance to the K/T boundary event. Earth and Planetary Science Letters, 92:317322.Google Scholar
Lopez-Ramos, . 1973. Estudio geológico de la Peninsula de Yucatán. Associatión Mexicana de Geólogos Petroleros Boletin, 25:2376.Google Scholar
Lopez-Ramos, . 1975. Geological summary of the Yucatan peninsula. In Nairn, A.E.M. and Stehli, F.G. (eds.) The ocean basins and margins. Volume 3. The Gulf of Mexico and the Caribbean, p. 257282. Plenum Press, New York.Google Scholar
Lyons, J.B. and Officer, C.B. 1992. Mineralogy and petrology of the Haiti Cretaceous/Tertiary section. Earth and Planetary Science Letters, 109:205224.Google Scholar
Lyons, J.B., Borella, P.E. and Lahodynsky, R. 1993. Planar lamellar substructures in quartz. Earth and Planetary Science Letters, 119:31440.Google Scholar
Marin, L.E. et al. 1994. The “upper Cretaceous unit” in the Chicxulub multiring basin: new age based on planktic foraminiferal assemblage, p. 77. Conference on new developments regarding the K/T and other catastrophics in earth history. Abstracts. Lunar and Planar Institute Contribution No. 825.Google Scholar
Maurrasse, F.J.-M.R. 1990. The Cretaceous-Tertiary impact site in the Caribbean. Geological Society of America Abstracts, 22, 7:A77.Google Scholar
Meyerhoff, A.A., Lyons, J.B. and Officer, C.B. 1994. Chicxulub structure: a volcanic sequence of Late Cretaceous age. Geology, 22:34.Google Scholar
Officer, C.B. and Lyons, J.B. 1993. A short note on the origin of the yellow glasses at the Haiti Cretaceous/Tertiary section. Earth and Planetary Science Letters, 118:349351.Google Scholar
Officer, C.B., Drake, C.L., Pindell, J.L. and Meyerhoff, A.A. 1992. Cretaceous-Tertiary events and the Caribbean caper. GSA Today, 2:6975.Google Scholar
Olmez, I., Finnegan, D.L. and Zoller, W.H. 1986. Iridium emissions from Kilauea volcano. Journal of Geophysical Research, 19:653663.Google Scholar
Quezada Muñeton, J.M. et al. 1992. The Chicxulub impact structure: shock deformation and target composition. Lunar and Planetary Science Conference Abstracts, 23:11211122.Google Scholar
Robertson, P.B., Dence, M.R. and Vos, M.A. 1968. Deformation in rock forming minerals from Canadian craters, p. 433452. In French, B.M. and Short, N.M. (eds.) Shock Metamorphism of Natural Materials. Mono Book, Baltimore.Google Scholar
Sclar, C.B., Short, N.M. and Cocks, G.G. 1968. Shock wave damage in quartz as revealed by electron and incident light microscopy, p. 483493. In French, B.M. and Short, N.M. (eds.) Shock Metamorphism of Natural Materials. Mono Book, Baltimore.Google Scholar
Sharpton, , et al. 1992. New links between the Chicxulub impact site and the Cretaceous/Tertiary boundary. Nature, 359:819821.Google Scholar
Smit, J. et al. 1992. Tektite bearing deep-water clastic unit at the Cretaceous-Tertiary boundary in northeastern Mexico. Geology, 20:99103.Google Scholar
Stinnesbeck, W. et al. 1993. Deposition of channel deposits proximal to the Cretaceous/Tertiary boundary in northeast Mexico: impact or gravity flow deposits? Geology, 21:797800.Google Scholar
Swisher, C.C. et al. 1992. Coeval 40Ar/39Ar ages of 65.0 million years ago from Chicxulub crater melt rock and Cretaceous/Tertiary boundary tektites. Science, 257:954958.Google Scholar
Toutain, J.-P. and Meyer, G. 1989. Iridium bearing sublimates at a hot spot volcano (Piton de la Fournaise). Geophysical Research Letters, 16:13911394.Google Scholar
Zoller, W.H., Parrington, J.R. and Phelan Kotra, J.M. 1983. Iridium enrichment in airborne particles from Kilauea volcano: January 1983. Science, 222:11181121.Google Scholar