Post on 31-Mar-2015
The first recorded impact The first recorded impact crater on the Earth: crater on the Earth:
Carancas, PeruCarancas, Peru
G. Tancredi and several G. Tancredi and several colleagues from Peru colleagues from Peru
and many other countriesand many other countries
Dpto. Astronomía, Fac. Ciencias, Dpto. Astronomía, Fac. Ciencias, Montevideo, UruguayMontevideo, Uruguay
gonzalo@fisica.edu.uygonzalo@fisica.edu.uy
¿What did happen?¿What did happen?
15/9/2007 – ~ 11:45 LT (16:45 UT) a bright fireball was 15/9/2007 – ~ 11:45 LT (16:45 UT) a bright fireball was observed in the sky, leaving behind an smoke trail. observed in the sky, leaving behind an smoke trail. Strong explosions lasting several seconds were heard in Strong explosions lasting several seconds were heard in an area of several tens of km long. An explosion was an area of several tens of km long. An explosion was observed as well as the formation of a thick cloud of dust observed as well as the formation of a thick cloud of dust like a mushroom cloud.like a mushroom cloud.The shock wave produce the vibration of several houses The shock wave produce the vibration of several houses and some animals were knocked down due to the shock and some animals were knocked down due to the shock wave. The roof of a shed was impacted by ejecta.wave. The roof of a shed was impacted by ejecta.In the site where the explosion and the dust cloud was In the site where the explosion and the dust cloud was observed, the local people found a ~15m crater. The observed, the local people found a ~15m crater. The crater was half-fill by underground water. The water was crater was half-fill by underground water. The water was bubbling and noxious fumes were coming out the water.bubbling and noxious fumes were coming out the water.Several pieces of atypical material was collected from Several pieces of atypical material was collected from inside and outside the crater.inside and outside the crater.Several persons got sick.Several persons got sick.
Preliminary considerationsPreliminary considerations
A stony meteorite enter the upper atmosphere at A stony meteorite enter the upper atmosphere at velocities ~12-20 km/s. As a consequence of the friction velocities ~12-20 km/s. As a consequence of the friction with the air molecules, the body heats up and material with the air molecules, the body heats up and material from the surface is vaporized. The hot gas cloud that is from the surface is vaporized. The hot gas cloud that is formed around the body is observed as a fireball formed around the body is observed as a fireball crossing the sky at high speed. The phenomena last just crossing the sky at high speed. The phenomena last just a few seconds. In its passage it leaves behind a smoke a few seconds. In its passage it leaves behind a smoke trail. Due to the supersonic speeds and possible trail. Due to the supersonic speeds and possible fragmentations, the shock wave produces a sonic boom fragmentations, the shock wave produces a sonic boom that last for several seconds.that last for several seconds.Though the body is largely decelerated in the passage Though the body is largely decelerated in the passage through the atmosphere, it retains an important fraction through the atmosphere, it retains an important fraction of its original spped and it impacts the ground producing of its original spped and it impacts the ground producing a crater.a crater.
The soundsThe sounds
The witnessThe witness
Photo of the smoke trailPhoto of the smoke trail
Crater: diameter 14mCrater: diameter 14m
Carancas meteoritesCarancas meteorites
Photo José Ishitsuka
Other meteorites foundOther meteorites found
60 gr
22 gr
20 gr
Chondrite
Achondrite
Iron
Photo 1: Transmitted light optical image. In the center a radiating pyroxene chondrule. Plane polarized light
Photo2: Detail of the radiating pyroxene chondrule. Cross polarized light
Photo3: Olivine rich object characterized by having a barred-olivine texturein the center and a thick olivine rim. Plane polarized light
MINERALOGY COMPOSITIONMINERALOGY COMPOSITION
Piroxene 1 Piroxene 1 40 %40 %OlivineOlivine 20 %20 %FeldespatFeldespat 10 %10 %Piroxene 2Piroxene 2 10 %10 %Opaque minerals accounting for 20 % of the Opaque minerals accounting for 20 % of the mass, they inlcude:mass, they inlcude:KamaciteKamacite 15% 15%TroiliteTroilite 5 %5 %CromiteCromite tracestracesCupper nativeCupper native tracestraces
Analysis from INGEMMET, Peru
Fer
rosi
lite
in O
rtop
iroxe
ne
Fayalite in Olivine
Clasification Clasification (M. E. Varela et al.)(M. E. Varela et al.)
Ordinary Chondrite type H4/5
Crater Aristarco, Moon
Impact Crateres by Impact Crateres by comets and asteroidscomets and asteroids
Meteor Crater Barringer, Arizona1.2 km, 49.000 yr
Crater Double Clearwater, Canada32 6 22kkm, 290 Myr
Crater Manicouagan, Canada100 km, 212 Myr
Tunguska, 1908 (photo taken by Kulik in 1928)
Recent records of impact cratersRecent records of impact craters
YearLocation of the
crater
Diameter of largest crater
Number of craters or
pits
Total mass of found
meteorites
Meteorite type
1998Kunya-Urgench, Turkmenistan
6 m Single 1.1 tons Chondrite H5
1990Sterlitamak, Russia
10 m Single 0.3 tons Iron IIIAB
1976 Jilin, China 4m Multiple 4 tons Chondrite H5
1947Sikhote-Alin, Russia
27 m Multiple 23 tons Iron IIAB
Jilin, China (1976)Jilin, China (1976)
Penetration hole
Sterlitamak, Rusia (1990)Sterlitamak, Rusia (1990)
Sikhote-Alin (1947)Sikhote-Alin (1947)
Sikhote-Alin strewn fieldSikhote-Alin strewn field
Carancas craterCarancas crater
Impact regimesImpact regimes
The size of the projectileThe size of the projectile
Impact Energy on the surfaceImpact Energy on the surface
Home experimentHome experiment
Ejecta at 300m in SW direction
The ejected materialThe ejected material
Big size ejecta at 100m in NE directionLocation of ejecta in NE direction
Roof of a shed at ~75m from the craterRoof of a shed at ~75m from the crater impacted by ejectaimpacted by ejecta
Distribution of ejected material Distribution of ejected material (Rosales et al. 2008)(Rosales et al. 2008)
Speed of the ejected materialSpeed of the ejected material
Shock Metamorphism of the target Shock Metamorphism of the target material and the projectilematerial and the projectile
French (1998)
Meteorites fragments embedded in the Meteorites fragments embedded in the soil soil (Harris et al. 2008)(Harris et al. 2008)
Quartz grains with shock Quartz grains with shock metamorphism due to impact metamorphism due to impact
(Harris et al. 2008)(Harris et al. 2008)
Conclusions about the Conclusions about the petrology studiespetrology studies
The meteoritic mass penetrated deeply at a high The meteoritic mass penetrated deeply at a high speed while coupling its energy to the subsurface speed while coupling its energy to the subsurface to produce surface spalls, inverted rim ejecta, to produce surface spalls, inverted rim ejecta, injection of meteoritic debris between contrasting injection of meteoritic debris between contrasting soil horizons, long crater rays, and excavation of soil horizons, long crater rays, and excavation of horizons not exposed on the surface.horizons not exposed on the surface.
Regarding the level of shock metamorphism of the Regarding the level of shock metamorphism of the target material, we estimate target material, we estimate
Pressures > 10GPaPressures > 10GPa
The impact velocity was > 3 km/s and possibly on The impact velocity was > 3 km/s and possibly on the order of 4 to 6 km/sthe order of 4 to 6 km/s
Infrasound and Seismic detectionsInfrasound and Seismic detections
Infrasound detection Infrasound detection (Brown et al. 2008)(Brown et al. 2008)
Infrasound station I08BO in La Paz, Bolivia (80 km from crater)
Infrasound station I41PY in Asuncíon, Paraguay (1617 km from crater)
Seismic detections Seismic detections (LePichon et al. 2008)(LePichon et al. 2008)
First seismic detection of an extraterrestrial impact on Earth
Estimate of the trajectory through the Estimate of the trajectory through the atmosphereatmosphere
Facts to take into account• Backazimuth from infrasound station I08BO
determined from the array of detectors• Arrival time in the seismic waves and of the
air shoch waves at the seismic and infrasound stations
• Witnesses that saw the fireball• Distribution of ejected material,
concentration in the SW direction
Orbital elements of the meteoroidOrbital elements of the meteoroid
Impact time: Impact time: 16h 40m 14s UT16h 40m 14s UT
Radiant: Radiant: Az ~ 80-110°Az ~ 80-110°
Alt ~ 45-60°Alt ~ 45-60°
Pre-atmospheric velocity: 12-18 km/sPre-atmospheric velocity: 12-18 km/s
Location of the radiants in equatorial Location of the radiants in equatorial coordinates relative to the Sun coordinates relative to the Sun (Tancredi et al. 2008)(Tancredi et al. 2008)
Radiants of NEAs
Sun
Anti-Sun
Elements compared with NEAsElements compared with NEAs
Direct EntryModelingResults:Example(D. Revelle et al.)
Why is this event so relevant?Why is this event so relevant?
1.1. Fresh fall with many witnessesFresh fall with many witnesses
2.2. An impact crater was formed An impact crater was formed
3.3. Impact at high latitude, less deceleration in the Impact at high latitude, less deceleration in the atmosphereatmosphere
4.4. Ordinary chondrite meteorite that survives the Ordinary chondrite meteorite that survives the passage through the atmospherepassage through the atmosphere
5.5. Several records of infrasound and seismic dataSeveral records of infrasound and seismic data
6.6. Collection of material from the ground and the Collection of material from the ground and the meteorite with shock metamorphismmeteorite with shock metamorphism
Preliminary ConclusionsPreliminary Conclusions
Initial Mass of the meteoroid: 7 to 12 tonInitial Mass of the meteoroid: 7 to 12 ton– Initial Diameter: 1.6 – 2 mInitial Diameter: 1.6 – 2 m
Initial Velocity: 12 – 17 km/sInitial Velocity: 12 – 17 km/s– Initial Energy: 0.12 – 0.41 kT TNTInitial Energy: 0.12 – 0.41 kT TNT
Trayectory with Az: 80° - 110°, Alt: 45° - 60°Trayectory with Az: 80° - 110°, Alt: 45° - 60°
Impact Velocity on the ground: ~> 3 km/s Impact Velocity on the ground: ~> 3 km/s
Mass of the impactor: 1 – 2.5 tonMass of the impactor: 1 – 2.5 ton– Diameter: 0.8–1.1m ; Impact Energy: ~2–4 tons TNTDiameter: 0.8–1.1m ; Impact Energy: ~2–4 tons TNT
There is no indications of large remnants of the There is no indications of large remnants of the meteorite inside the crater meteorite inside the crater (see Ishitsuka presentation)(see Ishitsuka presentation)
What else do we want to know?What else do we want to know?
Confirm the pressure and temperatures reached Confirm the pressure and temperatures reached at the time of impact and the velocity of the at the time of impact and the velocity of the impactorimpactorWhat does happen with the original meteorite? What does happen with the original meteorite? Was it fragmented and totally dispersed during Was it fragmented and totally dispersed during the impact?the impact?How was it possible that a chondrite meteorite of How was it possible that a chondrite meteorite of just a few meters in size could get through the just a few meters in size could get through the atmosphere without being completely disrupted?atmosphere without being completely disrupted?
In which conditions could this event In which conditions could this event happen again?happen again?
Research TeamResearch TeamG. TancrediG. Tancredi - - Dpto. Astronomía, Fac. Dpto. Astronomía, Fac. Ciencias, Iguá 4225, 11400 Montevideo, Ciencias, Iguá 4225, 11400 Montevideo, Uruguay, gonzalo@fisica.edu.uyUruguay, gonzalo@fisica.edu.uyJ. Ishitsuka, D. Rosales, E. VidalJ. Ishitsuka, D. Rosales, E. Vidal - - Instituto Geofísico del Perú, Lima, PerúInstituto Geofísico del Perú, Lima, PerúP. Schultz, R. S. HarrisP. Schultz, R. S. Harris - - Dept. Geological Sciences, Brown University, Rhode Dept. Geological Sciences, Brown University, Rhode Island, USA.Island, USA.P. BrownP. Brown - Dept. of Physics and Astronomy, University of Western Ontario, - Dept. of Physics and Astronomy, University of Western Ontario, London, ON N6A 3K7 CanadaLondon, ON N6A 3K7 CanadaD. RevelleD. Revelle - EES-2, Atmospheric, Climate and Environmental Dynamics Group - EES-2, Atmospheric, Climate and Environmental Dynamics Group – Meteorological Modeling Team, Los Alamos National Laboratory, P.O. Box – Meteorological Modeling Team, Los Alamos National Laboratory, P.O. Box 1663, MS D401, Los Alamos, NM 87545 USA1663, MS D401, Los Alamos, NM 87545 USAK. Antier, A. Le PichonK. Antier, A. Le Pichon - - Commissariat à l’Energie Atomique, Centre DAM - Ile Commissariat à l’Energie Atomique, Centre DAM - Ile de France, Département Analyse Surveillance Environnement, Bruyères-le-de France, Département Analyse Surveillance Environnement, Bruyères-le-Châtel, 91297 Arpajon Cedex, France.Châtel, 91297 Arpajon Cedex, France.S. BenaventeS. Benavente - - Universidad Nacional del Altiplano, Puno, PerúUniversidad Nacional del Altiplano, Puno, PerúP. Miranda, G. PereiraP. Miranda, G. Pereira - - Planetario Max Schreier, Universidad Mayor de San Planetario Max Schreier, Universidad Mayor de San Andrés, La Paz, BoliviaAndrés, La Paz, BoliviaM. E. VarelaM. E. Varela - - Complejo Astronómico El Leoncito – CASLEO, San Juan, Complejo Astronómico El Leoncito – CASLEO, San Juan, ArgentinaArgentinaF. BrandstätterF. Brandstätter - - Naturhistorisches Museum, Vienna, AustriaNaturhistorisches Museum, Vienna, Austria L. SánchezL. Sánchez - - Inst. Ciencias de la Tierra, Fac. Ciencias, Iguá 4225, 11400 Inst. Ciencias de la Tierra, Fac. Ciencias, Iguá 4225, 11400 Montevideo, UruguayMontevideo, Uruguay