Similar-sized collisions and the diversity of planets

Abstract It is assumed in models of terrestrial planet formation that colliding bodies simply merge. From this the dynamical and chemical properties (and habitability) of finished planets have been computed, and our own and other planetary systems compared to the results of these calculations. But efficient mergers may be exceptions to the rule, for the similar-sized collisions (SSCs) that dominate terrestrial planet formation, simply because moderately off-axis SSCs are grazing; their centers of mass overshoot. In a “hit and run” collision the smaller body narrowly avoids accretion and is profoundly deformed and altered by gravitational and mechanical torques, shears, tides, and impact shocks. Consequences to the larger body are minor in inverse proportion to its relative mass. Over the possible impact angles, hit-and-run is the most common outcome for impact velocities v imp between ∼ 1.2 and 2.7 times the mutual escape velocity v esc between similar-sized planets. Slower collisions are usually accretionary, and faster SSCs are erosive or disruptive, and thus the prevalence of hit-and-run is sensitive to the velocity regime during epochs of accretion. Consequences of hit-and-run are diverse. If barely grazing, the target strips much of the exterior from the impactor—any atmosphere and ocean, much of the crust—and unloads its deep interior from hydrostatic pressure for about an hour. If closer to head-on ( ∼ 30 – 45 ° ) a hit-and-run can cause the impactor core to plow through the target mantle, graze the target core, and emerge as a chain of diverse new planetoids on escaping trajectories. A hypothesis is developed for the diversity of next-largest bodies (NLBs) in an accreting planetary system—the bodies from which asteroids and meteorites derive. Because nearly all the NLBs eventually get accreted by the largest (Venus and Earth in our terrestrial system) or by the Sun, or otherwise lost, those we see today have survived the attrition of merger, evolving with each close call towards denser and volatile-poor bulk composition. This hypothesis would explain the observed density diversity of differentiated asteroids, and of dwarf planets beyond Neptune, in terms of episodic global-scale losses of rock or ice mantles, respectively. In an event similar to the Moon-forming giant impact, Mercury might have lost its original crust and upper mantle when it emerged from a modest velocity hit and run collision with a larger embryo or planet. In systems with super-Earths, profound diversity and diminished habitability is predicted among the unaccreted Earth-mass planets, as many of these will have be stripped of their atmospheres, oceans and crusts.

[1]  K. Tsiganis,et al.  Origin of the cataclysmic Late Heavy Bombardment period of the terrestrial planets , 2005, Nature.

[2]  W. Benz,et al.  Numerical simulations of impacts involving porous bodies: I. Implementing sub-resolution porosity in a 3D SPH hydrocode , 2008, 0807.1264.

[3]  Edward R. D. Scott,et al.  Chondrules and the Protoplanetary Disk , 2011 .

[4]  G. Wetherill,et al.  Occurrence of Giant Impacts During the Growth of the Terrestrial Planets , 1985, Science.

[5]  H. Haack,et al.  Catastrophic fragmentation of asteroids: evidence from meteorites , 1994 .

[6]  Space Science Reviews , 1962, Nature.

[7]  Erik Asphaug,et al.  Structure of Comet Shoemaker-Levy 9 Inferred from the Physics of Tidal Breakup , 1996 .

[8]  J. Schijf,et al.  Geochimica et Cosmochimica Acta , 2008 .

[9]  W. Benz,et al.  The Origin of Mercury , 2007 .

[10]  D. Davis,et al.  Collisional history of asteroids: Evidence from Vesta and the Hirayama families , 1985 .

[11]  Secular Resonances in Mean Motion Commensurabilities: The 2/1 and 3/2 Cases , 1993 .

[12]  T. Mexia,et al.  Author ' s personal copy , 2009 .

[13]  H. Melosh,et al.  The Stickney Impact of Phobos: A Dynamical Model , 1990 .

[14]  Willy Benz,et al.  Collisional stripping of Mercury's mantle , 1988 .

[15]  R. Canup Dynamics of Lunar Formation , 2004 .

[16]  R. Rosenfeld Nature , 2009, Otolaryngology--head and neck surgery : official journal of American Academy of Otolaryngology-Head and Neck Surgery.

[17]  R. Binzel,et al.  Mantle material in the main belt: Battered to bits? , 1996 .

[18]  Klaus Keil,et al.  Thermal alteration of asteroids: evidence from meteorites , 2000 .

[19]  E. Shoemaker Interpretation of Lunar Craters , 1962 .

[20]  J. S. Dohnanyi Collisional model of asteroids and their debris , 1969 .

[21]  Eiichiro Kokubo,et al.  Oligarchic growth of protoplanets , 1996 .

[22]  Erik Asphaug,et al.  Hit-and-run planetary collisions , 2006, Nature.

[23]  W. Bottke,et al.  The primordial excitation and clearing of the asteroid belt—Revisited , 2006 .

[24]  H. Haack,et al.  Formation of mesosiderites by fragmentation and reaccretion of a large differentiated asteroid , 2001 .

[25]  Jeffrey S. Oishi,et al.  Rapid planetesimal formation in turbulent circumstellar disks , 2007, Nature.

[26]  R. Cas,et al.  Reconstruction of a kimberlite eruption, using an integrated volcanological, geochemical and numerical approach: A case study of the Fox Kimberlite, NWT, Canada , 2009 .

[27]  K. Keil,et al.  Consequences of explosive eruptions on small Solar System bodies: the case of the missing basalts on the aubrite parent body , 1991 .

[28]  H. J. Melosh,et al.  Dynamic fragmentation in impacts: Hydrocode simulation of laboratory impacts , 1992 .

[29]  F. Nimmo,et al.  Isotopic outcomes of N-body accretion simulations: Constraints on equilibration processes during large impacts from Hf/W observations , 2006 .

[30]  B. Gladman,et al.  Mercurian impact ejecta: Meteorites and mantle , 2008, 0801.4038.

[31]  K. Rice,et al.  Protostars and Planets V , 2005 .

[32]  D. F. Merriam,et al.  Annual review of earth and planetary sciences v. 7, Editor: F. A. Donath; Associate Editors: F. G. Stehli, and G. W. Wetherill, Annual Reviews, Inc., 4139 El Camino Way, Palo Alto, California, 94036, 1979, 517p., 17 (U.S.), 17.50 elsewhere , 1980 .

[33]  D. Raine Essays in Nuclear Astrophysics , 1983 .

[34]  F. Albarède,et al.  A short timescale for terrestrial planet formation from Hf–W chronometry of meteorites , 2002, Nature.

[35]  S. Desch,et al.  A model of the thermal processing of particles in solar nebula shocks: Application to the cooling rates of chondrules , 2002 .

[36]  Michael R. Meyer,et al.  Evolution of Mid-Infrared Excess around Sun-like Stars: Constraints on Models of Terrestrial Planet Formation , 2007, 0712.1057.

[37]  John E. Chambers,et al.  Making the Terrestrial Planets: N-Body Integrations of Planetary Embryos in Three Dimensions , 1998 .

[38]  T. Rettig,et al.  Comet Shoemaker–Levy 9 Dust Size and Velocity Distributions , 2000 .

[39]  S. Love,et al.  Tidal Distortion and Disruption of Earth-Crossing Asteroids , 1997 .

[40]  Lars Hernquist,et al.  COLLISIONAL STRIPPING AND DISRUPTION OF SUPER-EARTHS , 2009, 0907.0234.

[41]  Erik Asphaug,et al.  Accretion Efficiency during Planetary Collisions , 2004 .

[42]  J. Delaney,et al.  Infrared spectroscopic measurements of CO2 and H2O in Juan de Fuca Ridge basaltic glasses , 1988 .

[43]  P. Murdin MONTHLY NOTICES OF THE ROYAL ASTRONOMICAL SOCIETY , 2005 .

[44]  H. Melosh,et al.  Cometary Nuclei and Tidal Disruption: The Geologic Record of Crater Chains on Callisto and Ganymede , 1996 .

[45]  P. Schultz,et al.  Impact‐induced frictional melting in ordinary chondrites: A mechanism for deformation, darkening, and vein formation , 2003 .

[46]  J. Chambers,et al.  The Primordial Excitation and Clearing of the Asteroid Belt , 2001 .

[47]  V. Safronov,et al.  Evolution of the protoplanetary cloud and formation of the earth and the planets , 1972 .

[48]  Willy Benz,et al.  Numerical simulations of impacts involving porous bodies: II. Comparison with laboratory experiments , 2009 .

[49]  G. Wetherill,et al.  Provenance of the terrestrial planets. , 1994, Geochimica et cosmochimica acta.

[50]  Harold F. Levison,et al.  Asteroids Were Born Big , 2009, 0907.2512.

[51]  A. Morbidelli,et al.  Terrestrial planet formation with strong dynamical friction , 2006 .

[52]  J. Chambers On the stability of a planet between Mars and the asteroid belt: Implications for the Planet V hypothesis , 2007 .

[53]  J. Baumgardner,et al.  The effects of a variation of the radial viscosity profile on mantle evolution , 2004 .

[54]  G. Wetherill Formation of the Terrestrial Planets , 1980 .

[55]  David J. Stevenson,et al.  Origin of the Moon-The Collision Hypothesis , 1987 .

[56]  H. Maring,et al.  Journal of Geophysical Research , 1949, Nature.

[57]  H. Haack,et al.  Rapid Timescales for Accretion and Melting of Differentiated Planetesimals Inferred from 26Al-26Mg Chronometry , 2005 .

[58]  Zdeněk Kopal,et al.  Physics and Astronomy of the Moon , 1962 .

[59]  E. Anders,et al.  Meteorites and the Early Solar System , 1971 .

[60]  H. Jeffreys The Relation of Cohesion to Roche's Limit , 1947 .

[61]  G. Wetherill An alternative model for the formation of the asteroids , 1992 .

[62]  Kelley,et al.  Rapid kimberlite ascent and the significance of Ar-Ar ages in xenolith phlogopites , 2000, Science.

[63]  K. Holsapple THE SCALING OF IMPACT PROCESSES IN PLANETARY SCIENCES , 1993 .

[64]  S. Murchie,et al.  Explosive volcanic eruptions on Mercury: Eruption conditions, magma volatile content, and implications for interior volatile abundances , 2008 .

[65]  Harold F. Levison,et al.  The formation of the Kuiper belt by the outward transport of bodies during Neptune's migration , 2003, Nature.

[66]  Erik Asphaug,et al.  Origin of the Moon in a giant impact near the end of the Earth's formation , 2001, Nature.

[67]  H. Jeffreys Origin of the Earth , 1952, Nature.

[68]  H. Haack,et al.  The thermal evolution of IVA iron meteorites: evidence from metallographic cooling rates , 1995 .

[69]  C. Chapman,et al.  What are the real constraints on the existence and magnitude of the late heavy bombardment , 2007 .

[70]  T. Spohn,et al.  Numerical Modeling of 26Al-Induced Radioactive Melting of Asteroids Considering Accretion , 2002 .

[71]  V. Kamenetsky,et al.  Carbonate‐chloride enrichment in fresh kimberlites of the Udachnaya‐East pipe, Siberia: A clue to physical properties of kimberlite magmas? , 2007 .

[72]  F. Nimmo,et al.  Implications of an impact origin for the martian hemispheric dichotomy , 2008, Nature.

[73]  M. E. Kipp,et al.  Geometric statistics and dynamic fragmentation , 1985 .

[74]  Erik Asphaug,et al.  Low-speed impacts between rubble piles modeled as collections of polyhedra, 2 , 2006 .

[75]  Kevin R. Housen,et al.  Impact Cratering: A Geologic Process , 1987 .

[76]  S. Weidenschilling Accretion of planetary embryos in the inner and outer solar system , 2008 .

[77]  Donald M. Hunten,et al.  Sulfur at Mercury, Elemental at the Poles and Sulfides in the Regolith , 1995 .

[78]  Robert Jedicke,et al.  The fossilized size distribution of the main asteroid belt , 2003 .

[79]  Ignasi Ribas,et al.  A ~5 M⊕ Super-Earth Orbiting GJ 436? The Power of Near-Grazing Transits , 2008, 0801.3230.

[80]  S. Raccichini,et al.  JOURNAL OF VULCANOLOGY AND GEOTHERMAL RESEARCH , 2013 .

[81]  W. Benz,et al.  Density of comet Shoemaker–Levy 9 deduced by modelling breakup of the parent 'rubble pile' , 1994, Nature.

[82]  S. Klein Astronomy and astrophysics with , 2008 .

[83]  William K. Hartmann,et al.  Satellite-Sized Planetesimals and Lunar Origin , 1975 .

[84]  M. Alidibirov,et al.  Magma fragmentation by rapid decompression , 1996, Nature.

[85]  W. Benz,et al.  Catastrophic Disruptions Revisited , 1999 .

[86]  William K. Hartmann,et al.  Planetesimals to planets: Numerical simulation of collisional evolution , 1978 .

[87]  Harold F. Levison,et al.  On the Character and Consequences of Large Impacts in the Late Stage of Terrestrial Planet Formation , 1999 .

[88]  E. Asphaug Impact origin of the Vesta family , 1997 .

[89]  H. Melosh,et al.  Understanding oblique impacts from experiments, observations, and modeling. , 2000, Annual review of earth and planetary sciences.

[90]  P. Tackley Convection in Io's asthenosphere: Redistribution of nonuniform tidal heating by mean flows , 2001 .

[91]  J. Chambers,et al.  Planets in the asteroid belt , 2001 .

[92]  James E. Gardner,et al.  Experimental constraints on degassing of magma: isothermal bubble growth during continuous decompression from high pressure , 1999 .

[93]  R. Canup Lunar-forming collisions with pre-impact rotation , 2007 .

[94]  W. Delamere,et al.  The internal structure of Jupiter family cometary nuclei from Deep Impact observations: The “talps” or “layered pile” model , 2007 .

[95]  C. Schafer,et al.  Collisions between equal-sized ice grain agglomerates , 2007, 0705.2672.

[96]  A. G. W. Cameron,et al.  The origin of the moon and the single-impact hypothesis III. , 1991 .

[97]  J. Cuzzi,et al.  Size-selective Concentration of Chondrules and Other Small Particles in Protoplanetary Nebula Turbulence , 2000, astro-ph/0009210.

[98]  Harry Y. McSween,et al.  Meteorites and the early solar system II , 2006 .

[99]  Y. Abe,et al.  Enhanced atmospheric loss on protoplanets at the giant impact phase in the presence of oceans , 2005, Nature.

[100]  Karim Shariff,et al.  Toward Planetesimals: Dense Chondrule Clumps in the Protoplanetary Nebula , 2008, 0804.3526.

[101]  V. Safronov,et al.  Relative sizes of the largest bodies during the accumulation of planets , 1969 .

[102]  E. Scott,et al.  Iron meteorite evidence for early formation and catastrophic disruption of protoplanets , 2007, Nature.

[103]  Erik Asphaug,et al.  Growth and Evolution of Asteroids , 2009 .

[104]  O. Aharonson,et al.  Mega-impact formation of the Mars hemispheric dichotomy , 2008, Nature.

[105]  Mike Burton,et al.  SO2 flux from Stromboli during the 2007 eruption: Results from the FLAME network and traverse measurements , 2009 .

[106]  S. Tremaine,et al.  Tidal disruption of viscous bodies , 1992 .