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NARROW
GeoRef Subject
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all geography including DSDP/ODP Sites and Legs
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Africa
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North Africa
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Western Sahara (1)
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West Africa
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Ghana
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Bosumtwi Crater (1)
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Mauritania (1)
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Asia
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Indian Peninsula
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India
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Maharashtra India
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Lonar Crater (2)
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Channeled Scabland (1)
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Chicxulub Crater (1)
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Europe
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Central Europe
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Germany
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Bavaria Germany
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Ries Crater (2)
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Western Europe
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Iceland (1)
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United States
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Arizona
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Coconino County Arizona
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Meteor Crater (12)
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commodities
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mineral resources (1)
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elements, isotopes
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metals
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nickel (1)
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fossils
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Plantae (1)
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geologic age
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Cenozoic
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Tertiary
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Paleogene
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Paleocene
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lower Paleocene
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K-T boundary (1)
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Mesozoic
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Cretaceous
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Upper Cretaceous
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K-T boundary (1)
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igneous rocks
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igneous rocks
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volcanic rocks
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basalts
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flood basalts (1)
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meteorites
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meteorites
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iron meteorites
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octahedrite
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Canyon Diablo Meteorite (1)
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minerals
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silicates
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framework silicates
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silica minerals
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coesite (1)
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lechatelierite (1)
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stishovite (1)
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orthosilicates
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nesosilicates
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zircon group
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zircon (1)
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Primary terms
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Africa
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North Africa
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Western Sahara (1)
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West Africa
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Ghana
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Bosumtwi Crater (1)
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Mauritania (1)
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Asia
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Indian Peninsula
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India
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Maharashtra India
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Lonar Crater (2)
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biography (1)
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Cenozoic
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Tertiary
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Paleogene
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Paleocene
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lower Paleocene
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K-T boundary (1)
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Earth (1)
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Europe
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Central Europe
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Germany
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Bavaria Germany
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Ries Crater (2)
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Western Europe
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Iceland (1)
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-
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geochemistry (2)
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geomorphology (1)
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igneous rocks
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volcanic rocks
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basalts
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flood basalts (1)
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maps (1)
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Mesozoic
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Cretaceous
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Upper Cretaceous
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K-T boundary (1)
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metals
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nickel (1)
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metamorphism (1)
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meteorites
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iron meteorites
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octahedrite
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Canyon Diablo Meteorite (1)
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mineral resources (1)
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mineralogy (1)
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Moon (1)
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petrology (2)
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Plantae (1)
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plate tectonics (1)
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sedimentary rocks
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clastic rocks
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sandstone (1)
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soils (1)
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tectonics (2)
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tektites (1)
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United States
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Arizona
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Coconino County Arizona
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Meteor Crater (12)
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sedimentary rocks
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sedimentary rocks
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clastic rocks
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sandstone (1)
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sedimentary structures
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channels (1)
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soils
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soils (1)
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Runoff required to drive postimpact gully development on the walls of Meteor Crater (Arizona, USA)
ABSTRACT Rampart craters are omnipresent features on volatile-rich solid planetary surfaces. This raises the question whether, and how many, rampart craters are present on Earth. We reviewed the terrestrial impact crater record with regard to possible rampart morphologies and present detailed morphological analyses of these terrestrial craters here. Our results show that the Ries crater in Germany, Bosumtwi crater in Ghana, Tenoumer crater in Mauritania, Lonar crater in India, and Meteor crater in the United States are terrestrial rampart craters. The Ries and Bosumtwi craters can be classified as double-layer ejecta (DLE) craters, whereas Tenoumer, Lonar, and Meteor craters can be classified as single-layer ejecta (SLE) craters. Tenoumer and Meteor craters show rampart as well as common lunar-like ejecta characteristics within their ejecta blankets and, thus, appear to be hybrid craters. In addition, we discuss seven crater structures that show at least some morphological or lithological peculiarities that could provide evidence for possible ejecta ramparts. Considering the low number of terrestrial impact craters with well-preserved ejecta blankets, the relatively high proportion of rampart craters is astonishing. Obviously, the formation of layered or rampart craters is a common and not a rare process on Earth.
Between Gilbert and Barringer: Joseph A. Munk as Unknown Pioneer of the Meteorite Model and Geotourist Exploitation of Coon Mountain (Arizona)
Transformations to granular zircon revealed: Twinning, reidite, and ZrO 2 in shocked zircon from Meteor Crater (Arizona, USA)
PERSPECTIVE
The surface of Mars: An unusual laboratory that preserves a record of catastrophic and unusual events
Catastrophic and unusual events on Earth such as bolide impacts, megafloods, supereruptions, flood volcanism, and subice volcanism may have devastating effects when they occur. Although these processes have unique characteristics and form distinctive features and deposits, we have difficulties identifying them and measuring the magnitude of their effects. Our difficulties with interpreting these processes and identifying their consequences are understandable considering their infrequency on Earth, combined with the low preservation potential of their deposits in the terrestrial rock record. Although we know these events do happen, they are infrequent enough that the deposits are poorly preserved on the geologically active face of the Earth, where erosion, volcanism, and tectonism constantly change the surface. Unlike the Earth, on Mars catastrophic and unusual features are well preserved because of the slow modification of the surface. Significant precipitation has not occurred on Mars for billions of years and there appears to be no discrete crustal plates to have undergone subduction and destruction. Therefore the ancient surface of Mars preserves geologic features and deposits that result from these extraordinary events. Also, unlike the other planets, Mars is the most similar to our own, having an atmosphere, surface ice, volcanism, and evidence of onceflowing water. So although our understanding of precursors, processes, and possible biological effects of catastrophic and unusual processes is limited on Earth, some of these mysteries may be better understood through investigating the surface of Mars.