List of impact structures on Earth

This list of impact structures on Earth contains a selection of the 190 confirmed craters given in the Earth Impact Database.^[1]

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To keep the lists manageable, only the largest impact structures within a time period are included. Alphabetical lists for different continents can be found under Impact structures by continent below.

Confirmed impact structures listed by size and age

These features were caused by the collision of meteors (consisting of large fragments of asteroids) or comets (consisting of ice, dust particles and rocky fragments) with the Earth. For eroded or buried craters, the stated diameter typically refers to the best available estimate of the original rim diameter, and may not correspond to present surface features. Time units are either in ka (thousands) or Ma (millions) of years.

10 ka or less

Less than ten thousand years old, and with a diameter of 100 m (330 ft) or more. The EID lists fewer than ten such craters, and the largest in the last 100,000 years (100 ka) is the 4.5 km (2.8 mi) Rio Cuarto crater in Argentina.^[2] However, there is some uncertainty regarding its origins^[3] and age, with some sources giving it as < 10 ka^[2]^[4] while the EID gives a broader < 100 ka.^[3]

The Kaali impacts (c. 1500 BC) during the Nordic Bronze Age may have influenced Estonian and Finnish mythology,^[5] the Campo del Cielo (c. 2500 BC) could be in the legends of some Native Argentine tribes,^[6]^[7] while Henbury (c. 2700 BC) has figured in Australian Aboriginal oral traditions.^[8]

Macha crater field map

One of the Kaali craters

Name	Location	Country	Diameter (km)	Age (ka)	Date	Coordinates
Wabar	Rub' al Khali desert	Saudi Arabia	000.1	< 00.2	~1800 AD	21°30′N 50°28′E / 21.500°N 50.467°E / 21.500; 50.467
Whitecourt	Alberta	Canada	000.04	< 01.1	900 AD	54°00′N 115°36′W / 54.000°N 115.600°W / 54.000; -115.600
Kaali	Saaremaa	Estonia	000.1	< 03.5	01500 BC	58°24′N 22°40′E / 58.400°N 22.667°E / 58.400; 22.667
Campo del Cielo	Chaco	Argentina	000.1^[7]	< 04.5	02500 BC	27°38′S 61°42′W / 27.633°S 61.700°W / -27.633; -61.700
Henbury	Northern Territory	Australia	000.2	< 04.7	02700 BC	24°34′S 133°8′E / 24.567°S 133.133°E / -24.567; 133.133
Morasko	Poznań	Poland	000.1	< 05.0^[9]	03000 BC	52°29′N 16°54′E / 52.483°N 16.900°E / 52.483; 16.900
Boxhole	Northern Territory	Australia	000.2	< 05.4	03400 BC	22°37′S 135°12′E / 22.617°S 135.200°E / -22.617; 135.200
Ilumetsa	Põlva County	Estonia	000.08	< 06.6	<4600 BC	57°57′N 27°24′E / 57.950°N 27.400°E / 57.950; 27.400
Macha	Sakha Republic	Russia	000.3	< 07.3	05300 BC	60°6′N 117°35′E / 60.100°N 117.583°E / 60.100; 117.583
Rio Cuarto (disputed)	Córdoba Province	Argentina	004.5	< 10 ?^[2]^[4]	<8000 BC	32°53′S 64°13′W / 32.883°S 64.217°W / -32.883; -64.217

For the Rio Cuarto craters, 2002 research suggests they may actually be aeolian structures.^[10] The EID gives a size of about 50 m (160 ft) for Campo del Cielo, but other sources quote 100 m (330 ft).^[7]

10 ka to 1 Ma

From between 10 thousand years and one million years ago, and with a diameter of less than one km (0.62 mi):

Name	Location	Country	Diameter (km)	Age (ka)	Coordinates
Wolfe Creek	Western Australia	Australia	0.9	< 120	19°10′18″S 127°47′44″E / 19.17167°S 127.79556°E / -19.17167; 127.79556
Monturaqui	Atacama Desert	Chile	0.455	640 ± 140	23°55′40″S 68°15′41″W / 23.92778°S 68.26139°W / -23.92778; -68.26139

From between ten thousand years and one million years ago, and with a diameter of one km (0.62 mi) or more. The largest in the last one million years is the 14-kilometre (8.7 mi) Zhamanshin crater in Kazakhstan and has been described as being capable of producing a nuclear-like winter.^[11]

However, the currently unknown source of the enormous Australasian strewnfield (c. 780 ka) could be a crater about 100 km (62 mi) across.^[12]^[13]

Meteor Crater, 1.2 km (0.75 mi)

Tenoumer crater, 1.9 km (1.2 mi)

Name	Location	Country	Diameter (km)	Age (ka)	Coordinates
Tenoumer	Sahara Desert	Mauritania	01.9	021	22°55′2″N 10°24′28″W / 22.91722°N 10.40778°W / 22.91722; -10.40778
Yilan	Heilongjiang	China	01.85	049	46°23′4″N 129°19′39″E / 46.38444°N 129.32750°E / 46.38444; 129.32750
Meteor Crater	Arizona	United States	01.2	049	35°1′39″N 111°1′22″W / 35.02750°N 111.02278°W / 35.02750; -111.02278
Xiuyan	Xiuyan	China	01.8	050	40°21′42″N 123°27′47″E / 40.36167°N 123.46306°E / 40.36167; 123.46306
Lonar	Maharashtra	India	01.8	052	19°58′37″N 76°30′32″E / 19.97694°N 76.50889°E / 19.97694; 76.50889
Agoudal^[14]	Atlas Mountains	Morocco	03.0	105	31°59′N 5°30′W / 31.983°N 5.500°W / 31.983; -5.500
Tswaing	Pretoria Saltpan	South Africa	01.1	220	25°24′32″S 28°4′58″E / 25.40889°S 28.08278°E / -25.40889; 28.08278
Zhamanshin	Kazakhstan	Kazakhstan	14.0	900 ± 100	48°24′0″N 60°58′0″E / 48.40000°N 60.96667°E / 48.40000; 60.96667

1 Ma to 10 Ma

Elgygytgyn, 18 km (11 mi)

Bosumtwi, 10 km (6.2 mi)

From between 1 and 10 million years ago, and with a diameter of 5 km or more. If uncertainties regarding its age are resolved, then the largest in the last 10 million years would be the 52-kilometre (32 mi) Karakul crater which is listed in EID with an age of less than 5 Ma, or the Pliocene. The large but apparently craterless Eltanin impact (2.5 Ma) into the Pacific Ocean has been suggested as contributing to the glaciations and cooling during the Pliocene.^[15]

Name	Location	Country	Diameter (km)	Age (Million years)	Coordinates
Bosumtwi	Ashanti	Ghana	0010	;01.1	6°30′N 1°25′W / 6.500°N 1.417°W / 6.500; -1.417
Elgygytgyn	Chukotka Autonomous Okrug	Russia	0018	;03.5	67°30′N 172°00′E / 67.500°N 172.000°E / 67.500; 172.000
Bigach	Kazakhstan	Kazakhstan	0008	;05	48°34′N 82°1′E / 48.567°N 82.017°E / 48.567; 82.017
Karla	Tatarstan	Russia	0010	;05	54°55′N 48°2′E / 54.917°N 48.033°E / 54.917; 48.033
Karakul	Pamir Mountains	Tajikistan	0052	< 5 ?^[16]^[17]	39°1′N 73°27′E / 39.017°N 73.450°E / 39.017; 73.450 (Kara-Kul)
Eltanin impact	Southern Ocean	SW of Chile	none	2.5	57°47′S 90°47′W / 57.783°S 90.783°W / -57.783; -90.783

10 Ma or more

Craters with diameter 20 km (12 mi) or more are all older than 10 Ma, except possibly Karakul, 52 km (32 mi), whose age is uncertain.

There are more than forty craters of such size. The Chicxulub impact has been widely been considered the most likely cause for the Cretaceous–Paleogene mass extinction, with some scholars linking other impacts like the Popigai impact in Russia and the Chesapeake Bay impact to later extinction events, though the causal relationship has been questioned.^[18]

Sudbury Basin, 130 km (81 mi)

Chicxulub crater, 150 km (93 mi)

Popigai impact structure, 100 km (62 mi)

Manicouagan impact structure, 100 km (62 mi)

Acraman crater, 85 to 90 km (53 to 56 mi)

Charlevoix impact structure, 54 km (34 mi)

Nördlinger Ries, 24 km (15 mi)

Name	Location	Country	Diameter (km)	Age (million years)	Coordinates
Vredefort	Free State	South Africa	160	2023 ± 4	27°0′S 27°30′E / 27.000°S 27.500°E / -27.000; 27.500 (Vredefort)
Chicxulub	Yucatán	Mexico	150	66.051 ± 0.031	21°20′N 89°30′W / 21.333°N 89.500°W / 21.333; -89.500 (Chicxulub)
Sudbury	Ontario	Canada	130	1849	46°36′N 81°11′W / 46.600°N 81.183°W / 46.600; -81.183 (Sudbury)
Popigai	Siberia	Russia	100	35.7±0.2	71°39′N 111°11′E / 71.650°N 111.183°E / 71.650; 111.183 (Popigai)
Manicouagan	Quebec	Canada	100	215.56 ± 0.05	51°23′N 68°42′W / 51.383°N 68.700°W / 51.383; -68.700 (Manicouagan)
Acraman	South Australia	Australia	90	580	32°1′S 135°27′E / 32.017°S 135.450°E / -32.017; 135.450 (Acraman)
Morokweng	Kalahari Desert	South Africa	70	146.06 ± 0.16	26°28′S 23°32′E / 26.467°S 23.533°E / -26.467; 23.533 (Morokweng)
Kara	Nenetsia	Russia	65	70.3	69°6′N 64°9′E / 69.100°N 64.150°E / 69.100; 64.150 (Kara)
Beaverhead	Idaho and Montana	United States	60	600	44°15′N 114°0′W / 44.250°N 114.000°W / 44.250; -114.000 (Beaverhead)
Tookoonooka	Queensland	Australia	55	133–112	27°7′S 142°50′E / 27.117°S 142.833°E / -27.117; 142.833 (Tookoonooka)
Charlevoix	Quebec	Canada	54	342	47°32′N 70°18′W / 47.533°N 70.300°W / 47.533; -70.300 (Charlevoix)
Siljan Ring	Dalarna	Sweden	52	377	61°2′N 14°52′E / 61.033°N 14.867°E / 61.033; 14.867 (Siljan)
Karakul	Pamir Mountains	Tajikistan	52	5? 25?	39°1′N 73°27′E / 39.017°N 73.450°E / 39.017; 73.450 (Kara-Kul)
Montagnais	Nova Scotia	Canada	45	50.5	42°53′N 64°13′W / 42.883°N 64.217°W / 42.883; -64.217 (Montagnais)
Araguainha	Central Brazil	Brazil	40	244.4	16°47′S 52°59′W / 16.783°S 52.983°W / -16.783; -52.983 (Araguainha)
Chesapeake Bay	Virginia	United States	40	34.86 ± 0.23	37°17′N 76°1′W / 37.283°N 76.017°W / 37.283; -76.017 (Chesapeake Bay)
Mjølnir	Barents Sea	Norway	40	142	73°48′N 29°40′E / 73.800°N 29.667°E / 73.800; 29.667 (Mjølnir)
Puchezh-Katunki	Nizhny Novgorod Oblast	Russia	40	195.9 ± 1.0	56°58′N 43°43′E / 56.967°N 43.717°E / 56.967; 43.717 (Puchezh-Katunki)
Saint Martin	Manitoba	Canada	40	227.8 ± 1.1	51°47′N 98°32′W / 51.783°N 98.533°W / 51.783; -98.533 (Saint Martin)
Woodleigh	Western Australia	Australia	40	364	26°3′S 114°40′E / 26.050°S 114.667°E / -26.050; 114.667 (Woodleigh)
Carswell	Saskatchewan	Canada	39	115	58°27′N 109°30′W / 58.450°N 109.500°W / 58.450; -109.500 (Carswell)
Clearwater West	Quebec	Canada	36	290	56°13′N 74°30′W / 56.217°N 74.500°W / 56.217; -74.500 (Clearwater West)
Manson	Iowa	United States	35	74	42°35′N 94°33′W / 42.583°N 94.550°W / 42.583; -94.550 (Manson)
Hiawatha	Greenland	Denmark	31	57.99 ± 0.54	78°50′N 67°18′W / 78.833°N 67.300°W / 78.833; -67.300
Slate Islands	Ontario	Canada	30	450	48°40′N 87°0′W / 48.667°N 87.000°W / 48.667; -87.000 (Slate Islands)
Yarrabubba	Western Australia	Australia	30	2229	27°10′S 118°50′E / 27.167°S 118.833°E / -27.167; 118.833 (Yarrabubba)
Keurusselkä	Western Finland	Finland	30	1500–1400	62°8′N 24°36′E / 62.133°N 24.600°E / 62.133; 24.600 (Keurusselkä)
Shoemaker	Western Australia	Australia	30	1630?	25°52′S 120°53′E / 25.867°S 120.883°E / -25.867; 120.883 (Shoemaker)
Mistastin	Newfoundland and Labrador	Canada	28	36.4	55°53′N 63°18′W / 55.883°N 63.300°W / 55.883; -63.300 (Mistastin)
Clearwater East	Quebec	Canada	26	465	56°4′N 74°6′W / 56.067°N 74.100°W / 56.067; -74.100 (Clearwater East)
Kamensk	Southern Federal District	Russia	25	49	48°21′N 40°30′E / 48.350°N 40.500°E / 48.350; 40.500 (Kamensk)
Steen River	Alberta	Canada	25	91	59°30′N 117°38′W / 59.500°N 117.633°W / 59.500; -117.633 (Steen River)
Strangways	Northern Territory	Australia	25	646	15°12′S 133°35′E / 15.200°S 133.583°E / -15.200; 133.583 (Strangways)
Tunnunik	Northwest Territories	Canada	25	450–430	72°28′N 113°58′W / 72.467°N 113.967°W / 72.467; -113.967 (Tunuunik)
Boltysh	Kirovohrad Oblast	Ukraine	24	65.17	48°54′N 32°15′E / 48.900°N 32.250°E / 48.900; 32.250 (Boltysh)
Nördlinger Ries	Bavaria, Baden-Württemberg	Germany	24	14.808 ± 0.038	48°53′N 10°34′E / 48.883°N 10.567°E / 48.883; 10.567 (Nördlinger Ries)
Presqu'île	Quebec	Canada	24	less than 500	49°43′N 74°48′W / 49.717°N 74.800°W / 49.717; -74.800 (Presqu'ile)
Haughton	Nunavut	Canada	23	39	75°23′N 89°40′W / 75.383°N 89.667°W / 75.383; -89.667 (Haughton)
Lappajärvi	Western Finland	Finland	23	77.85 ± 0.78	63°12′N 23°42′E / 63.200°N 23.700°E / 63.200; 23.700 (Lappajärvi)
Rochechouart	France	France	23	206.92 ± 0.32^[19]	45°49′N 0°47′E / 45.817°N 0.783°E / 45.817; 0.783 (Rochechouart)
Gosses Bluff	Northern Territory	Australia	22	142.5	23°49′S 132°18′E / 23.817°S 132.300°E / -23.817; 132.300 (Gosses Bluff)
Amelia Creek	Northern Territory	Australia	20	1660–600	20°55′S 134°50′E / 20.917°S 134.833°E / -20.917; 134.833 (Amelia Creek)
Logancha	Siberia	Russia	20	40	65°31′N 95°56′E / 65.517°N 95.933°E / 65.517; 95.933 (Logancha)
Obolon'	Poltava Oblast	Ukraine	20	169	49°35′N 32°55′E / 49.583°N 32.917°E / 49.583; 32.917 (Obolon')

Impact structures by continent

As of 2022^[update], the Earth Impact Database (EID) contains 190 confirmed impact structures.^[1] The table below is arranged by the continent's percentage of the Earth's land area, and where Asian and Russian structures are grouped together per EID convention. The global distribution of known impact structures apparently shows a surprising asymmetry,^[20] with the small but well-funded European continent having a large percentage of confirmed impact structures. It is suggested this situation is an artifact, highlighting the importance of intensifying research in less studied areas like Antarctica, South America and elsewhere.^[20]

Links in the column "Continent" will give a list of craters for that continent.

Continent	Continent's % of Earth's land area	Continent's % of the 190 known impact structures	Number of impact structures
Asia and Russia	30%	16%	31
Africa	20%	11%	20
North America	16%	32%	60
South America	12%	6%	11
Antarctica	9%	0%	0
Europe	7%	22%	41
Australia	6%	14%	27
Total	100%	100%	190

References

^ ^a ^b "Earth Impact Database". University of New Brunswick. Archived from the original on 2013-07-08. Retrieved 2016-04-30.
^ ^a ^b ^c Bland, Phil A.; de Souza Filho, C. R.; Timothy Jull, A. J.; Kelley, Simon P.; Hough, Robert Michael; Artemieva, N. A.; Pierazzo, E.; Coniglio, J.; Pinotti, Lucio; Evers, V.; Kearsley, Anton; (2002); "A possible tektite strewn field in the Argentinian Pampa", Science, volume 296, issue 5570, pp. 1109–12
^ ^a ^b "Rio Cuarto". Earth Impact Database. Planetary and Space Science Centre University of New Brunswick Fredericton. Retrieved 2009-08-19.
^ ^a ^b Schultz, Peter H.; Lianza, Ruben E. (1992) "Recent grazing impacts on the Earth recorded in the Rio Cuarto crater field, Argentina", Nature 355, pp. 234–37 (16 January 1992)
^ Haas, Ain; Peekna, Andres; Walker, Robert E. "Echoes of Ancient Cataclysms in the Baltic Sea" (PDF). Electronic Journal of Folklore. Retrieved 2008-10-26.
^ Benítez, Giménez; López, Alejandro M.; Mammana, Luis A. "Meteorites of Campo del Cielo: Impact on the indian culture".
^ ^a ^b ^c Bobrowsky, Peter T.; Rickman, Hans (2007). Comet/asteroid impacts and human society: an interdisciplinary approach. Springer. pp. 30–31. ISBN 978-3-540-32709-7.
^ Hamacher, Duane W.; Goldsmith, John. "Aboriginal oral traditions of Australian impact craters" (PDF). Archived from the original (PDF) on 2018-08-20. Retrieved 2016-04-09.
^ Stankowski, Wojciech; Raukas, Anto; Bluszcz, Andrzej; Fedorowicz, Stanisław. "Luminescence dating of the Morasko (Poland), Kaali, Ilumetsa, and Tsõõrikmäe (Estonia) meteorite craters" (PDF).
^ Cione, Alberto L.; et al. (2002). "Putative Meteoritic Craters in Río Cuarto (Central Argentina) Interpreted as Eolian Structures". Earth, Moon, and Planets. 91 (1): 9–24. Bibcode:2002EM&P...91....9C. doi:10.1023/A:1021209417252. S2CID 122467947.
^ Essay "Impact Cratering on Earth", based on: Grieve, Richard A. F. (1990). "Impact cratering on the Earth". Scientific American. 262 (4): 66–73. Bibcode:1990SciAm.262d..66G. doi:10.1038/scientificamerican0490-66.
^ Povenmire, Harold; Liu, W.; Xianlin, Luo (1999) "Australasian tektites found in Guangxi Province, China", in Proceedings of the 30th Annual Lunar and Planetary Science Conference, Houston, March 1999
^ Glass, Billy P.; Pizzuto, James E. (1994) "Geographic variation in Australasian microtektite concentrations: Implications concerning the location and size of the source crater", Journal of Geophysical Research, vol. 99, no. E9, 19075–81, September 1994
^ "Agoudal". Earth Impact Database. Planetary and Space Science Centre University of New Brunswick Fredericton. Retrieved 2016-08-18.
^ University of New South Wales (19 September 2012). "Did a Pacific Ocean meteor trigger the Ice Age?". Retrieved 8 October 2012.
^ "Kara-Kul". Earth Impact Database. Planetary and Space Science Centre University of New Brunswick Fredericton. Retrieved 2009-08-15.
^ Gurov, Eugene P.; Gurova, H. P.; Rakitskaya, R. B.; Yamnichenko, A. Yu. (1993). "The Karakul depression in Pamirs – the first impact structure in central Asia" (PDF). Lunar and Planetary Science. XXIV: 591–92. Bibcode:1993LPI....24..591G.
^ Rampino, Michael R. (February 2020). "Relationship between impact-crater size and severity of related extinction episodes". Earth-Science Reviews. 201: 102990. Bibcode:2020ESRv..20102990R. doi:10.1016/j.earscirev.2019.102990.
^ Cohen, Benjamin E.; Mark, Darren F.; Lee, Martin R.; Simpson, Sarah L. (2017-08-01). "A new high-precision ⁴⁰Ar/³⁹Ar age for the Rochechouart impact structure: At least 5 Ma older than the Triassic–Jurassic boundary". Meteoritics & Planetary Science. 52 (8): 1600–11. Bibcode:2017M&PS...52.1600C. doi:10.1111/maps.12880. hdl:10023/10787. ISSN 1945-5100.
^ ^a ^b Prezzi, Claudia B.; Orgeira, María Julia; Acevedo, Rogelio D.; Ponce, Juan Federico; Martinez, Oscar; Rabassa, Jorge O.; Corbella, Hugo; Vásquez, Carlos; González-Guillot, Mauricio; Subías, Ignacio; (2011); "Geophysical characterization of two circular structures at Bajada del Diablo (Patagonia, Argentina): Indication of impact origin", Physics of the Earth and Planetary Interiors, vol. 192, pp. 21–34

External links

Impact Database (formerly Suspected Earth Impact Sites list) maintained by David Rajmon for Impact Field Studies Group, US
Impact Meteor Crater Viewer Google Maps Page with Locations of Meteor Craters around the world
Impact Craters at Lunar and Planetary Institute

[EID-1] "Earth Impact Database". University of New Brunswick. Archived from the original on 2013-07-08. Retrieved 2016-04-30.

[bland-2] Bland, Phil A.; de Souza Filho, C. R.; Timothy Jull, A. J.; Kelley, Simon P.; Hough, Robert Michael; Artemieva, N. A.; Pierazzo, E.; Coniglio, J.; Pinotti, Lucio; Evers, V.; Kearsley, Anton; (2002); "A possible tektite strewn field in the Argentinian Pampa", Science, volume 296, issue 5570, pp. 1109–12

[rio-3] "Rio Cuarto". Earth Impact Database. Planetary and Space Science Centre University of New Brunswick Fredericton. Retrieved 2009-08-19.

[schultz-4] Schultz, Peter H.; Lianza, Ruben E. (1992) "Recent grazing impacts on the Earth recorded in the Rio Cuarto crater field, Argentina", Nature 355, pp. 234–37 (16 January 1992)

[5] Haas, Ain; Peekna, Andres; Walker, Robert E. "Echoes of Ancient Cataclysms in the Baltic Sea" (PDF). Electronic Journal of Folklore. Retrieved 2008-10-26.

[6] Benítez, Giménez; López, Alejandro M.; Mammana, Luis A. "Meteorites of Campo del Cielo: Impact on the indian culture".

[Bobrowsky-7] Bobrowsky, Peter T.; Rickman, Hans (2007). Comet/asteroid impacts and human society: an interdisciplinary approach. Springer. pp. 30–31. ISBN 978-3-540-32709-7.

[8] Hamacher, Duane W.; Goldsmith, John. "Aboriginal oral traditions of Australian impact craters" (PDF). Archived from the original (PDF) on 2018-08-20. Retrieved 2016-04-09.

[9] Stankowski, Wojciech; Raukas, Anto; Bluszcz, Andrzej; Fedorowicz, Stanisław. "Luminescence dating of the Morasko (Poland), Kaali, Ilumetsa, and Tsõõrikmäe (Estonia) meteorite craters" (PDF).

[Cione2002-10] Cione, Alberto L.; et al. (2002). "Putative Meteoritic Craters in Río Cuarto (Central Argentina) Interpreted as Eolian Structures". Earth, Moon, and Planets. 91 (1): 9–24. Bibcode:2002EM&P...91....9C. doi:10.1023/A:1021209417252. S2CID 122467947.

[11] Essay "Impact Cratering on Earth", based on: Grieve, Richard A. F. (1990). "Impact cratering on the Earth". Scientific American. 262 (4): 66–73. Bibcode:1990SciAm.262d..66G. doi:10.1038/scientificamerican0490-66.

[povenmire-12] Povenmire, Harold; Liu, W.; Xianlin, Luo (1999) "Australasian tektites found in Guangxi Province, China", in Proceedings of the 30th Annual Lunar and Planetary Science Conference, Houston, March 1999

[glass1994-13] Glass, Billy P.; Pizzuto, James E. (1994) "Geographic variation in Australasian microtektite concentrations: Implications concerning the location and size of the source crater", Journal of Geophysical Research, vol. 99, no. E9, 19075–81, September 1994

[14] "Agoudal". Earth Impact Database. Planetary and Space Science Centre University of New Brunswick Fredericton. Retrieved 2016-08-18.

[15] University of New South Wales (19 September 2012). "Did a Pacific Ocean meteor trigger the Ice Age?". Retrieved 8 October 2012.

[karakul-16] "Kara-Kul". Earth Impact Database. Planetary and Space Science Centre University of New Brunswick Fredericton. Retrieved 2009-08-15.

[17] Gurov, Eugene P.; Gurova, H. P.; Rakitskaya, R. B.; Yamnichenko, A. Yu. (1993). "The Karakul depression in Pamirs – the first impact structure in central Asia" (PDF). Lunar and Planetary Science. XXIV: 591–92. Bibcode:1993LPI....24..591G.

[18] Rampino, Michael R. (February 2020). "Relationship between impact-crater size and severity of related extinction episodes". Earth-Science Reviews. 201: 102990. Bibcode:2020ESRv..20102990R. doi:10.1016/j.earscirev.2019.102990.

[19] Cohen, Benjamin E.; Mark, Darren F.; Lee, Martin R.; Simpson, Sarah L. (2017-08-01). "A new high-precision ⁴⁰Ar/³⁹Ar age for the Rochechouart impact structure: At least 5 Ma older than the Triassic–Jurassic boundary". Meteoritics & Planetary Science. 52 (8): 1600–11. Bibcode:2017M&PS...52.1600C. doi:10.1111/maps.12880. hdl:10023/10787. ISSN 1945-5100.

[Prezzi-20] Prezzi, Claudia B.; Orgeira, María Julia; Acevedo, Rogelio D.; Ponce, Juan Federico; Martinez, Oscar; Rabassa, Jorge O.; Corbella, Hugo; Vásquez, Carlos; González-Guillot, Mauricio; Subías, Ignacio; (2011); "Geophysical characterization of two circular structures at Bajada del Diablo (Patagonia, Argentina): Indication of impact origin", Physics of the Earth and Planetary Interiors, vol. 192, pp. 21–34

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