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Impact event

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Artist's impression of a major impact event. The collision between Earth
and an asteroid a few kilometers in diameter may release as much energy as
several million nuclear weapons detonating simultaneously.

An *impact event* is the collision of a large meteorite , asteroid , comet
, or other celestial object with the Earth or another planet . Throughout
recorded history, hundreds of minor impact events (and exploding bolides )
have been reported, with some occurrences causing deaths, injuries,
property damage or other significant localised consequences.^[1] An impact
event in an ocean or sea may create a tsunami (a giant wave), which can
cause destruction both at sea and on land near a seashore .

The latest major impact event occurred in Kaali , Estonia about 700 BC.

Impact events have been a plot and background element in science fiction
since knowledge of real impacts became established in the scientific
mainstream.


Contents

[hide ]

* 1 Sizes and frequencies 
* 2 Geology of Earth-impact events 
* 3 Recent prehistoric impact events 
* 4 Modern impact events 
* 5 Mass extinctions and impacts 
* 6 End of civilization 
* 7 Impact events in popular culture

o 7.1 Social attitudes 
o 7.2 Science fiction novels 
o 7.3 Movies 
o 7.4 Games 
o 7.5 Biblical prophecies 
* 8 See also 
* 9 References 
* 10 Further reading 
* 11 External links 


[edit ] Sizes and frequencies

Small objects frequently collide with the Earth. There is an inverse
relationship between the size of the object and the frequency that such
objects hit the earth. Asteroids with a 1 km (0.62 mi) diameter strike the
Earth every 500,000 years on average.^[2] Large collisions – with 5 km
(3 mi) objects – happen approximately once every ten million years. The
last known impact of an object of 10 km (6 mi) or more in diameter was at
the Cretaceous-Tertiary extinction event 65 million years ago.

Asteroids with diameters of 5 to 10 m (16 to 33 ft) enter the Earth's
atmosphere approximately once per year, with as much energy as Little Boy
, the atomic bomb dropped on Hiroshima, approximately 15 kilotonnes of
TNT. These ordinarily explode in the upper atmosphere , and most or all of
the solids are vaporized .^[3] Objects with diameters over 50 m (164 ft)
strike the Earth approximately once every thousand years, producing
explosions comparable to the one known to have detonated above Tunguska in
1908.^[4] At least one known asteroid with a diameter of over 1 km (0.62
mi), (29075) 1950 DA , has a possibility of colliding with Earth on March
16, 2880, with a Torino Scale rating of two.

Objects with diameters smaller than 10 m (33 ft) are called meteoroids (or
meteorites if they strike the ground). An estimated 500 meteorites reach
the surface each year, but only 5 or 6 of these are typically recovered
and made known to scientists.


[edit ] Geology of Earth-impact events

Earth has gone through periods of abrupt and catastrophic change, some due
to the impact of large asteroids and comets on the planet. A few of these
impacts may have caused massive climate change and the extinction of large
numbers of plant and animal species .

The Moon is widely attributed to a huge impact early in Earth's history .  
Impact events earlier in the history of Earth have been credited with
creative as well as destructive events; it has been proposed that the
water in the Earth's oceans was delivered by impacting comets, and some
have suggested that the origins of life may have been influenced by
impacting objects by bringing organic chemicals or lifeforms to the
Earth's surface, a theory known as exogenesis .



Eugene Merle Shoemaker was first to prove that meteor impacts have
affected the Earth .

These modified views of the Earth's history did not emerge until
relatively recently, chiefly due to a lack of direct observations and the
difficulty in recognizing the signs of an Earth impact because of erosion
and weathering. Large-scale terrestrial impacts of the sort that produced
the Barringer Crater , locally known as Meteor Crater , northeast of
Flagstaff, Arizona, are rare. Instead, it was widely thought that
cratering was the result of volcanism : the Barringer Crater, for example,
was ascribed to a prehistoric volcanic explosion (not an unreasonable
hypothesis, given that the volcanic San Francisco Peaks stand only 30
miles (48 km) to the west). Similarly, the craters on the surface of the
Moon were ascribed to volcanism.

It was not until 1903–1905 that the Barringer Crater was correctly
identified as being an impact crater, and it was not until as recently as
1963 that research by Eugene Merle Shoemaker conclusively proved this
hypothesis. The findings of late 20th-century space exploration and the
work of scientists such as Shoemaker demonstrated that impact cratering
was by far the most widespread geological process at work on the solar
system's solid bodies. Every surveyed solid body in the solar system was
found to be cratered, there was no reason to believe that the Earth had
somehow escaped bombardment from space. The first observation of a major
impact event occurred in 1994: the collision of the comet Shoemaker-Levy 9
with Jupiter ; to date, no such events have been observed on Earth.

Based on crater formation rates determined from the Earth's closest
celestial partner, the Moon , astrogeologists have determined that during
the last 600 million years, the Earth has been struck by 60 objects of a
diameter of 5 km (3 mi) or more. The smallest of these impactors would
release the equivalent of ten million megatons of TNT and leave a crater
95 km (60 mi) across. For comparison, the largest nuclear weapon ever
detonated, the Tsar Bomba , had a yield of 50 megatons.


[edit ] Recent prehistoric impact events

In addition to the extremely large impacts that happen every few tens of
millions of years, there are many smaller impacts that occur more
frequently but which leave correspondingly smaller traces behind. Due to
the strong forces of erosion at work on Earth, only relatively recent
examples of these smaller impacts are known. A few of the more famous or
interesting examples are:



Aerial view of Barringer Crater in Arizona

* Barringer Crater in the USA, the first crater to be proven the result of
an impact, ~50,000 years old. * the Rio Cuarto craters in Argentina,
produced by an asteroid striking Earth at a very low angle, ~10,000 years
old. * the Lonar crater lake in Asia, which now has a flourishing
semi-tropical jungle around it, ~52,000 years old (though a study
published in 2010 gives a much greater age). * the Henbury craters in
Australia (~5,000 years old), and Kaali craters in Estonia (~2700 years
old), apparently produced by objects which broke up before impact.

The Clovis comet hypothesis is a theory that an air burst from a large
comet above or even into the Laurentide Ice Sheet north of the Great Lakes
set all of the North American continent ablaze around 12,900 years ago.
The theory attempts to explain the extinction of most of the large animals
in North America and the demise of the North American stone age Clovis
culture about at the end of the Pleistocene epoch. Proponents claim the
existence of a mysterious charred carbon-rich layer of soil found at some
50 Clovis-age sites across the continent.^[5] It has been criticized for
not being consistent with paleoindian population estimates.^[6]


More recent prehistoric impacts are theorized by the Holocene Impact
Working Group, including Dallas Abbott of Columbia University's
Lamont-Doherty Earth Observatory in Palisades, N.Y.^[7] This group points
to four enormous chevron sediment deposits at the southern end of
Madagascar, containing deep-ocean microfossils fused with metals typically
formed by cosmic impacts. All of the chevrons point toward a spot in the
middle of the Indian Ocean where newly discovered Burckle crater ,^[8] 29
km (18 mi) in diameter, or about 25 times larger than Barringer Crater,
lies 3,800 m (12,500 ft) below the surface. This group posits that a large
asteroid or comet impact c. 2800-3000 BC produced a mega-tsunami at least
180 m (590 ft) high, a catastrophic event that would have affected
humanity's cradles of civilization .^[9] If this and other recent impacts
prove correct, the rate of asteroid impacts is much higher than currently
thought.

Years 533–534 CE ± 2 impact events have been proposed by the
dendrochronologist Mike Baillie as a possible cause of several brief
(typically 5-10 year) climatic downturns recorded in ancient tree ring
patterns. In his book /Exodus to King Arthur : Catastrophic Encounters
with Comets/, he highlights four such events and suggests that these might
have been caused by the dust veils thrown up by the impact of cometary
debris.


[edit ] Modern impact events

A Chinese record states that 10,000 people were killed in Shanxi Province
in 1490 by a hail of "falling stones"; some astronomers surmise that this
may describe the breakup of a large asteroid, although they find the
number of deaths implausible.^[10]


Kamil Crater , discovered from *Google Earth * image review in Egypt , 45
meters in diameter, 10 meters deep is thought to have been formed less
than 3,500 years ago in a then-unpopulated region of Western Egypt. It was
found February 19, 2009 by V. de Michelle on a Google Earth image of the
^[11] East Uweinat Desert, Egypt.

The Mahuika crater may have resulted from a modern impact event. The
crater is located south of the Snares Islands (120 km (70 mi) southwest of
Stewart Island) on the southern New Zealand shelf ^[12] and is
approximately 20 kilometres (12 mi) wide. Material extracted from Siple
Dome ice core melt water indicates that the impact occurred around 1443
A.D.

The Wabar craters in Arabia may have been created sometime during the past
few hundred years.



Trees knocked over by the Tunguska blast.

The most significant recorded impact in recent times was the Tunguska
event , which occurred in Siberia , Russia, in 1908. This incident
involved an explosion that was probably caused by the airburst of an
asteroid or comet 5 to 10 km (3.1 to 6.2 mi) above the Earth's surface,
felling an estimated 80 million trees over 2,150 km^2 (830 sq mi).

The late Eugene Shoemaker of the U.S. Geological Survey came up with an
estimate of the rate of Earth impacts, and suggested that an event about
the size of the nuclear weapon that destroyed Hiroshima occurs about once
a year. Such events would seem to be spectacularly obvious, but they
generally go unnoticed for a number of reasons: the majority of the
Earth's surface is covered by water; a good portion of the land surface is
uninhabited; and the explosions generally occur at relatively high
altitude, resulting in a huge flash and thunderclap but no real damage.
Some have been observed. Noteworthy examples include the Sikhote-Alin
Meteorite fall in Primorye , far eastern Russia, in 1947, and the
Revelstoke fireball of 1965, which occurred over the snows of British
Columbia, Canada.

A small number of meteorite falls have been observed with automated
cameras and recovered following calculation of the impact point. The first
of these was the Pribram meteorite , which fell in Czechoslovakia (now the
Czech Republic ) in 1959.^[13] In this case, two cameras used to
photograph meteors captured images of the fireball. The images were used
both to determine the location of the stones on the ground and, more
significantly, to calculate for the first time an accurate orbit for a
recovered meteorite.

Following the Pribram fall, other nations established automated observing
programs aimed at studying infalling meteorites. One of these was the
/Prairie Network/, operated by the Smithsonian Astrophysical Observatory
from 1963 to 1975 in the midwestern US. This program also observed a
meteorite fall, the /Lost City/ chondrite, allowing its recovery and a
calculation of its orbit.^[14] Another program in Canada, the Meteorite
Observation and Recovery Project, ran from 1971 to 1985. It too recovered
a single meteorite, /Innisfree/, in 1977.^[15] Finally, observations by
the European Fireball Network, a descendant of the original Czech program
that recovered Pribram, led to the discovery and orbit calculations for
the Neuschwanstein meteorite in 2002.^[16]

The only reported fatality from meteorite impacts is an Egyptian dog that
was killed in 1911 by the Nakhla meteorite , although this report is
disputed. The meteorites that struck this area were identified in the
1980s as Martian in origin.

The first known modern case of a human hit by a space rock occurred on
November 30, 1954, in Sylacauga, Alabama .^[17] There a 4 kg (8.8 lb)
stone chondrite crashed through a roof and hit Ann Hodges in her living
room after it bounced off her radio. She was badly bruised. Several
persons have since claimed to have been struck by 'meteorites' but no
verifiable meteorites have resulted.

On August 10, 1972, a meteor which became known as The Great Daylight 1972
Fireball was witnessed by many people moving north over the Rocky
Mountains from the U.S. Southwest to Canada. It was filmed by a tourist at
the Grand Teton National Park in Wyoming with an 8-millimeter color movie
camera.^[18] The object was in the range of size from a car to a house and
could have ended its life in a Hiroshima-sized blast, but there was never
any explosion. Analysis of the trajectory indicated that it never came
much lower than 58 km (36 mi) off the ground, and the conclusion was that
it had grazed Earth's atmosphere for about 100 seconds, then skipped back
out of the atmosphere to return to its orbit around the Sun.

In the dark morning hours of January 18, 2000, a fireball exploded over
the city of Whitehorse in the Canadian Yukon at an altitude of about 26 km
(16 mi), lighting up the night like day. The meteor that produced the
fireball was estimated to be about 4.6 m (15 ft) in diameter and with a
weight of 180 tonnes. This blast was also featured on The Science Channel
series /Killer Asteroids/, with several witness reports from residents in
Atlin, British Columbia .



Comet Shoemaker-Levy 9 's scar on Jupiter (dark area near Jupiter's limb )


A picture of the Jupiter 2009 impact event blemish captured by the Keck II
telescope and its near-infrared camera at Mauna Kea Observatory , on July
20.

A meteor was observed striking Reisadalen in Nordreisa municipality in
Troms County, Norway, on June 7, 2006. Although initial witness reports
stated that the resultant fireball was equivalent to the Hiroshima nuclear
explosion , scientific analysis places the force of the blast at anywhere
from 100-500 tonnes TNT equivalent – around 3% of Hiroshima's
yield.^[19]

On September 15, 2007, a chondritic meteor crashed near the village of
Carancas in southeastern Peru near Lake Titicaca , leaving a water-filled
hole and spewing gases across the surrounding area. Many residents became
ill, apparently from the noxious gases shortly after the impact.

On November 21, 2009, a fireball was sighted in South Africa by police and
traffic cameras. The probable meteor may have landed in a remote area on
the Botswana border, and likely made little impact.^[20]


Many impact events occur without being observed by anyone on the ground.
Between 1975 and 1992, American missile early warning satellites picked up
136 major explosions in the upper atmosphere. In the November 21, 2002,
edition of the journal /Nature/, Peter Brown of the University of Western
Ontario reported on his study of U.S. early warning satellite records for
the proceeding 8 years. He identified 300 flashes caused by 1 to 10 m (3
to 33 ft) sized meteors in that time period and estimated the rate of
Tunguska -sized events as once in 400 years.^[21] Eugene Shoemaker
estimated that one of such magnitude occurs about once every 300 years,
though more recent analyses have suggested he exaggerated by an order of
magnitude.

The 1994 impact of Comet Shoemaker-Levy 9 with Jupiter served as a
"wake-up call", and astronomers responded by starting programs such as
Lincoln Near-Earth Asteroid Research (LINEAR), Near-Earth Asteroid
Tracking (NEAT), Lowell Observatory Near-Earth Object Search (LONEOS) and
several others which have drastically increased the rate of asteroid
discovery.

In 1998, two comets were observed plunging into the Sun in close
succession. The first of these was on June 1 and the second the next day.
A video of this, followed by a dramatic ejection of solar gas (supposedly
unrelated to the impacts), can be found at the NASA^[22] website. Both of
these comets evaporated before coming into contact with the surface of the
Sun. According to a theory by NASA Jet Propulsion Laboratory scientist
Zdeněk Sekanina, the latest impactor to actually make contact with the
Sun was the "supercomet" Howard-Koomen-Michels on August 30, 1979.^[23]
(See also sungrazer .)

On October 7, 2008, a meteroid labeled 2008 TC3 was tracked for 20 hours
as it approached Earth and as it fell through the atmosphere and impacted
in Sudan. This was the first time an object was detected before it reached
the atmosphere and hundreds of pieces of the meteorite were recovered from
the Nubian Desert .^[24]

On July 19, 2009, a new black spot about the size of Earth was discovered
in Jupiter's southern hemisphere by an amateur astronomer. Thermal
infrared analysis showed it was warm and spectroscopic methods detected
ammonia. JPL scientists confirmed that another impact event on Jupiter had
occurred, probably a small undiscovered comet or other icy body.^[25]
^[26] ^[27]


[edit ] Mass extinctions and impacts

In the past 540 million years there have been five generally-accepted,
major mass extinctions that on average extinguished half of all species .  
One of the largest mass extinction to have affected life on Earth was in
the Permian-Triassic , which ended the Permian period 250 million years
ago and killed off 90% of all species^[28] ; life on Earth took 30 million
years to recover.^[29] The cause of the Permian-Triassic extinction is
still matter of debate with the age and origin of proposed impact craters,
i.e. the Bedout High structure, hypothesized to be associated with it are
still controversial.^[30] The last such mass extinction led to the demise
of the dinosaurs and coincided with a large meteorite impact; this is the
Cretaceous–Tertiary extinction event (also known as the K–T extinction
event). There is no definitive evidence of impacts leading to the four
other major mass extinctions .

In 1980, physicist Luis Alvarez ; his son, geologist Walter Alvarez ; and
nuclear chemists Frank Asaro and Helen V. Michael from the University of
California, Berkeley discovered unusually high concentrations of iridium
in a specific layer of rock strata in the Earth's crust. Iridium is an
element that is rare on Earth but relatively abundant in many meteorites .
From the amount and distribution of iridium present in the
65-million-year-old "iridium layer", the Alvarez team later estimated that
an asteroid of 10 to 14 km (6 to 9 mi) must have collided with the earth.
This iridium layer at the K–T boundary has been found worldwide at 100
different sites. Multidirectionally shocked quartz (coesite), which is
only known to form as the result of large impacts or atomic bomb
explosions, has also been found in the same layer at more than 30 sites.
Soot and ash at levels tens of thousands times normal levels were found
with the above.

Anomalies in chromium isotopic ratios found within the K-T boundary layer
strongly support the impact theory.^[/citation needed /] Chromium isotopic
ratios are homogeneous within the earth, therefore these isotopic
anomalies exclude a volcanic origin which was also proposed as a cause for
the iridium enrichment. Furthermore the chromium isotopic ratios measured
in the K-T boundary are similar to the chromium isotopic ratios found in
carbonaceous chondrites . Thus a probable candidate for the impactor is a
carbonaceous asteroid but also a comet is possible because comets are
assumed to consist of material similar to carbonaceous chondrites.

Probably the most convincing evidence for a worldwide catastrophe was the
discovery of the crater which has since been named Chicxulub Crater . This
crater is centered on the Yucatán Peninsula of Mexico and was discovered
by Tony Camargo and Glen Pentfield while working as geophysicists for the
Mexican oil company PEMEX . What they reported as a circular feature later
turned out to be a crater estimated to be 180 km (110 mi) in diameter.
Other researchers would later find that the end-Cretaceous extinction
event that wiped out the dinosaurs had lasted for thousands of years
instead of millions of years as had previously been thought. This
convinced the vast majority of scientists that this extinction resulted
from a point event that is most probably an extraterrestrial impact and
not from increased volcanism and climate change (which would spread its
main effect over a much longer time period).

Recently, several craters around the world have been dated to
approximately the same age as Chicxulub — for example, the Silverpit
crater in the United Kingdom, the Boltysh crater in Ukraine and the Shiva
crater near India. This has led to the suggestion that the Chicxulub
impact was one of several that occurred almost simultaneously, perhaps due
to a disrupted comet impacting the Earth in a similar manner to the
collision of Comet Shoemaker-Levy 9 with Jupiter in 1994.

It was the lack of high concentrations of iridium and shocked quartz which
has prevented the acceptance of the idea that the Permian extinction was
also caused by an impact. During the late Permian all the continents were
combined into one supercontinent named Pangaea and all the oceans formed
one superocean, Panthalassa . If an impact occurred in the ocean and not
on land at all, then there would be little shocked quartz released (since
oceanic crust has relatively little silica ) and much less material.

Although there is now general agreement that there was a huge impact at
the end of the Cretaceous that led to the iridium enrichment of the K-T
boundary layer, remnants have been found of other impacts of the same
order of magnitude that did not result in any mass extinctions, and there
is no clear linkage between an impact and any other incident of mass
extinction. Nonetheless it is now widely believed that mass extinctions
due to impacts are an occasional event in the history of Earth ^[/citation
needed /] .

Paleontologists David M. Raup and Jack Sepkoski have proposed that an
extinction occurs roughly every 26 million years (though many are
relatively minor). This led physicist Richard A. Muller to suggest that
these extinctions could be due to a hypothetical companion star to the Sun
called Nemesis periodically disrupting the orbits of comets in the Oort
cloud , and leading to a large increase in the number of comets reaching
the inner solar system where they might hit Earth.

Indeed, in the early history of the Earth (about four billion years ago)
bolide impacts were almost certainly common since the solar system
contained far more discrete bodies than at present. Such impacts could
have included strikes by asteroids hundreds of kilometers in diameter,
with explosions so powerful that they vaporized all the Earth's oceans. It
was not until this heavy bombardment slackened that life appears to have
begun to evolve on Earth.

The leading theory of the Moon's origin is the giant impact theory , which
states that Earth was once hit by a planetoid the size of Mars; if this
theory holds then that impact was almost certainly the largest hit Earth
ever suffered.


[edit ] End of civilization

An impact event is commonly seen as a scenario^[31] ^[32] that would bring
about the end of civilization . In 2000, /Discover Magazine/ published a
list of 20 possible sudden doomsday scenarios with impact event listed as
the No. 1 most likely to occur.^[33] Until the 1980s this idea was not
taken seriously, but all that changed after the discovery of the Chicxulub
Crater which was further reinforced by witness to the Comet Shoemaker-Levy
9 event.^[/citation needed /]



[edit ]
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