fbpx
Wikipedia

Planet V

January 01, 1970

Not to be confused with Phaeton (hypothetical planet).

Planet V is a hypothetical fifth terrestrial planet posited by NASA scientists John Chambers and Jack J. Lissauer to have once existed between Mars and the asteroid belt. In their hypothesis the Late Heavy Bombardment of the Hadean era began after perturbations from the other terrestrial planets caused Planet V's orbit to cross into the asteroid belt. Chambers and Lissauer presented the results of initial tests of this hypothesis during the 33rd Lunar and Planetary Science Conference, held from March 11 through 15, 2002.[1]

Hypothesis edit

In the Planet V hypothesis, five terrestrial planets were produced during the planetary formation era. The fifth terrestrial planet began on a low-eccentricity orbit between Mars and the asteroid belt with a semi-major axis between 1.8 and 1.9 AU. While long-lived, this orbit was unstable on a time-scale of 600 Myr. Eventually perturbations from the other inner planets drove Planet V onto a high-eccentricity orbit which crossed into the inner asteroid belt. Asteroids were scattered onto Mars-crossing and resonant orbits by close encounters with Planet V. Many of these asteroids then evolved onto Earth-crossing orbits temporarily enhancing the lunar impact rate. This process continued until Planet V was lost most likely by impacting the Sun after entering the ν6 secular resonance.[2]

Tests and results edit

As an initial test of the Planet V hypothesis, Chambers and Lissauer conducted 36 computer simulations of the Solar System with an additional terrestrial planet. A variety of parameters were used to determine the impacts of Planet V's initial orbit and mass. The mean time at which Planet V was lost was found to increase from 100 Myr to 400 Myr as its initial semi-major axis was increased from 1.8 to 1.9 AU. Results consistent with the current Solar System were most common with a 0.25 Mars mass Planet V. In cases with a larger mass Planet V collisions between planets were likely. Overall a third of these simulations were deemed successful in that Planet V was removed without impacting another planet. To test whether Planet V could increase the lunar impact rate they added test particles to one of the simulations. After an initial decline the number of particles on Earth-crossing orbits increased after Planet V entered the inner asteroid belt a pattern consistent with the LHB. These results were presented at the 33rd Lunar and Planetary Science Conference.[2]

In a later article published in the journal Icarus in 2007, Chambers reported the results of 96 simulations examining the orbital dynamics of the Solar System with five terrestrial planets. In a quarter of the simulations Planet V was ejected or impacted the Sun without other terrestrial planets suffering collisions. This result was most frequent if Planet V's mass was less than 0.25 of Mars. The other simulations were not considered successful because Planet V either survived for the entire 1 billion year length of the simulations, or collisions occurred between planets.[3]

The terrestrial Planet V hypothesis was examined by Ramon Brasser and Alessandro Morbidelli in 2011. Their work was the first to focus on the magnitude of the bombardment caused by Planet V. Brasser and Morbidelli calculated that to create the Late Heavy Bombardment Planet V would have to remove 95% of the pre-LHB main asteroid belt or 98% of the inner asteroid belt (semi-major axis < 2.5 AU). Depleting the main asteroid belt by 95% with a 0.5 Mars-mass Planet V was found to require it remain in an orbit crossing the entire asteroid belt for 300 million years. This orbital evolution was not observed in any simulations; Planet V typically entered an Earth-crossing orbit resulting in a short dynamic lifetime before entering such an orbit. In a few percent of simulations Planet V remained in the inner belt long enough to produce the LHB. However, producing the LHB from the inner asteroid belt would require the inner asteroid belt to have begun with 4–13 times the mass, and 10–24 time the orbital density, as the rest of the asteroid belt.[4]

Brasser and Morbidelli also examined the hypothesis that Planet V caused the LHB by disrupting putative asteroid belts between the terrestrial planets. The authors noted that the lack of present-day detection of the remnants of these belts places a significant constraint on this hypothesis, requiring that they be 99.99% depleted before Planet V was lost. While this occurred in 66% of the simulations compatible with the current Solar System for a Venus-Earth belt, it did not occur in any for the Earth-Mars belt due to its higher stability. Morbidelli and Brasser concluded from this result that an Earth-Mars belt could not have contained a significant population. Although Planet V could generate a Late Heavy Bombardment by disrupting a massive Venus-Earth belt alone, the authors observed that significant differences in these belts has not been produced in planetary formation models.[4]

Alternate version edit

An impact of Planet V onto Mars, forming the Borealis Basin has recently been proposed as an explanation for the Late Heavy Bombardment. Debris from this impact would have a different size distribution than the asteroid belt with a smaller fraction of large bodies and would result in a lower number of giant impact basins relative to craters.[5][6]

See also edit

References edit

  1. ^ Space.com: "Long-Destroyed Fifth Planet May Have Caused Lunar Cataclysm, Researchers Say"
  2. ^ a b Chambers, J. E.; Lissauer, J. J. (2002). "A New Dynamical Model for the Lunar Late Heavy Bombardment" (PDF). Lunar and Planetary Institute Science Conference Abstracts. 33: 1093. Bibcode:2002LPI....33.1093C.
  3. ^ Chambers, J. E. (2007). "On the stability of a planet between Mars and the asteroid belt: Implications for the Planet V hypothesis". Icarus. 189 (2): 386–400. Bibcode:2007Icar..189..386C. doi:10.1016/j.icarus.2007.01.016.
  4. ^ a b Brasser, R; Morbidelli, A. (2011). "The terrestrial Planet V hypothesis as the mechanism for the origin of the late heavy bombardment". Astronomy & Astrophysics. 535: A41. Bibcode:2011A&A...535A..41B. doi:10.1051/0004-6361/201117336.
  5. ^ Minton, D. A.; Jackson, A. P.; Asphaug, E.; Fassett, C. I.; Richardson, J. E. (2015). "Debris from Borealis Basin Formation as the Primary Impactor Population of Late Heavy Bombardment" (PDF). Workshop on Early Solar System Impact Bombardment III. 1826: 3033. Bibcode:2015LPICo1826.3033M.
  6. ^ Minton, David A.; Richard, James E.; Fassett, Caleb I. (2015). "Re-examining the main asteroid belt as the primary source of ancient lunar craters". Icarus. 247: 172–190. arXiv:1408.5304. Bibcode:2015Icar..247..172M. doi:10.1016/j.icarus.2014.10.018. S2CID 55230320.

January 01, 1970
planet, confused, with, phaeton, hypothetical, planet, hypothetical, fifth, terrestrial, planet, posited, nasa, scientists, john, chambers, jack, lissauer, have, once, existed, between, mars, asteroid, belt, their, hypothesis, late, heavy, bombardment, hadean,. Not to be confused with Phaeton hypothetical planet Planet V is a hypothetical fifth terrestrial planet posited by NASA scientists John Chambers and Jack J Lissauer to have once existed between Mars and the asteroid belt In their hypothesis the Late Heavy Bombardment of the Hadean era began after perturbations from the other terrestrial planets caused Planet V s orbit to cross into the asteroid belt Chambers and Lissauer presented the results of initial tests of this hypothesis during the 33rd Lunar and Planetary Science Conference held from March 11 through 15 2002 1 Contents 1 Hypothesis 2 Tests and results 3 Alternate version 4 See also 5 ReferencesHypothesis editIn the Planet V hypothesis five terrestrial planets were produced during the planetary formation era The fifth terrestrial planet began on a low eccentricity orbit between Mars and the asteroid belt with a semi major axis between 1 8 and 1 9 AU While long lived this orbit was unstable on a time scale of 600 Myr Eventually perturbations from the other inner planets drove Planet V onto a high eccentricity orbit which crossed into the inner asteroid belt Asteroids were scattered onto Mars crossing and resonant orbits by close encounters with Planet V Many of these asteroids then evolved onto Earth crossing orbits temporarily enhancing the lunar impact rate This process continued until Planet V was lost most likely by impacting the Sun after entering the n6 secular resonance 2 Tests and results editAs an initial test of the Planet V hypothesis Chambers and Lissauer conducted 36 computer simulations of the Solar System with an additional terrestrial planet A variety of parameters were used to determine the impacts of Planet V s initial orbit and mass The mean time at which Planet V was lost was found to increase from 100 Myr to 400 Myr as its initial semi major axis was increased from 1 8 to 1 9 AU Results consistent with the current Solar System were most common with a 0 25 Mars mass Planet V In cases with a larger mass Planet V collisions between planets were likely Overall a third of these simulations were deemed successful in that Planet V was removed without impacting another planet To test whether Planet V could increase the lunar impact rate they added test particles to one of the simulations After an initial decline the number of particles on Earth crossing orbits increased after Planet V entered the inner asteroid belt a pattern consistent with the LHB These results were presented at the 33rd Lunar and Planetary Science Conference 2 In a later article published in the journal Icarus in 2007 Chambers reported the results of 96 simulations examining the orbital dynamics of the Solar System with five terrestrial planets In a quarter of the simulations Planet V was ejected or impacted the Sun without other terrestrial planets suffering collisions This result was most frequent if Planet V s mass was less than 0 25 of Mars The other simulations were not considered successful because Planet V either survived for the entire 1 billion year length of the simulations or collisions occurred between planets 3 The terrestrial Planet V hypothesis was examined by Ramon Brasser and Alessandro Morbidelli in 2011 Their work was the first to focus on the magnitude of the bombardment caused by Planet V Brasser and Morbidelli calculated that to create the Late Heavy Bombardment Planet V would have to remove 95 of the pre LHB main asteroid belt or 98 of the inner asteroid belt semi major axis lt 2 5 AU Depleting the main asteroid belt by 95 with a 0 5 Mars mass Planet V was found to require it remain in an orbit crossing the entire asteroid belt for 300 million years This orbital evolution was not observed in any simulations Planet V typically entered an Earth crossing orbit resulting in a short dynamic lifetime before entering such an orbit In a few percent of simulations Planet V remained in the inner belt long enough to produce the LHB However producing the LHB from the inner asteroid belt would require the inner asteroid belt to have begun with 4 13 times the mass and 10 24 time the orbital density as the rest of the asteroid belt 4 Brasser and Morbidelli also examined the hypothesis that Planet V caused the LHB by disrupting putative asteroid belts between the terrestrial planets The authors noted that the lack of present day detection of the remnants of these belts places a significant constraint on this hypothesis requiring that they be 99 99 depleted before Planet V was lost While this occurred in 66 of the simulations compatible with the current Solar System for a Venus Earth belt it did not occur in any for the Earth Mars belt due to its higher stability Morbidelli and Brasser concluded from this result that an Earth Mars belt could not have contained a significant population Although Planet V could generate a Late Heavy Bombardment by disrupting a massive Venus Earth belt alone the authors observed that significant differences in these belts has not been produced in planetary formation models 4 Alternate version editAn impact of Planet V onto Mars forming the Borealis Basin has recently been proposed as an explanation for the Late Heavy Bombardment Debris from this impact would have a different size distribution than the asteroid belt with a smaller fraction of large bodies and would result in a lower number of giant impact basins relative to craters 5 6 See also editDisrupted planet Fifth planet hypothetical Nice model Phaeton hypothetical planet List of hypothetical solar system objectsReferences edit Space com Long Destroyed Fifth Planet May Have Caused Lunar Cataclysm Researchers Say a b Chambers J E Lissauer J J 2002 A New Dynamical Model for the Lunar Late Heavy Bombardment PDF Lunar and Planetary Institute Science Conference Abstracts 33 1093 Bibcode 2002LPI 33 1093C Chambers J E 2007 On the stability of a planet between Mars and the asteroid belt Implications for the Planet V hypothesis Icarus 189 2 386 400 Bibcode 2007Icar 189 386C doi 10 1016 j icarus 2007 01 016 a b Brasser R Morbidelli A 2011 The terrestrial Planet V hypothesis as the mechanism for the origin of the late heavy bombardment Astronomy amp Astrophysics 535 A41 Bibcode 2011A amp A 535A 41B doi 10 1051 0004 6361 201117336 Minton D A Jackson A P Asphaug E Fassett C I Richardson J E 2015 Debris from Borealis Basin Formation as the Primary Impactor Population of Late Heavy Bombardment PDF Workshop on Early Solar System Impact Bombardment III 1826 3033 Bibcode 2015LPICo1826 3033M Minton David A Richard James E Fassett Caleb I 2015 Re examining the main asteroid belt as the primary source of ancient lunar craters Icarus 247 172 190 arXiv 1408 5304 Bibcode 2015Icar 247 172M doi 10 1016 j icarus 2014 10 018 S2CID 55230320 Retrieved from https en wikipedia org w index php title Planet V amp oldid 1172546992, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.