IAR   05382
INSTITUTO ARGENTINO DE RADIOASTRONOMIA
Unidad Ejecutora - UE
artículos
Título:
Impact disruption of primordial planetesimals
Autor/es:
PARISI, M. GABRIELA
Revista:
PLANETARY AND SPACE SCIENCE
Editorial:
PERGAMON-ELSEVIER SCIENCE LTD
Referencias:
Lugar: Amsterdam; Año: 2012
ISSN:
0032-0633
Resumen:
It isusually assumed that 1-10-km  sized planetesimals are formed    through coagulation processes and     continue to agglomerate via pairwise mergers. However, recent models of planetesimal formation   suggest that planetesimals of 100-1000km were produced directly from small solid particles without experiencing accretion through intermediate sizes. At present, if planetesimals were born small or bigis a matter of debate. We investigate if planetesimals in the range10-1000 km suffer growth or disruption as they collide.The collisional energy required for disruption is computed as a function of the planetesimals radius and velocity in terms of their orbital semiaxis  and eccentricity. We obtain that growth of planetesimals of  10 -100 km in the asteroid belt and the Kuiper belt requires  eccentricities much lower than what we observe today. Simulations of accretion in the terrestrial and giant planets region show that planetesimals of 10-100 km reach values of the eccentricity which lie at the disruption eccentricity limit obtained in this work. We obtain that planetesimals growth requires a very  cold disk during all the accretionary process, which seems to be difficult to achieve. We conclude that large planetesimals may be formed either invoking modern scenarios of gravitational instability or by accreting small bodies only. Planetesimals of intermediate sizes would then be the  result of disruption events. We obtain that accretion requires an impactor target mass ratio smaller than 0.1-0.01. This implies that the exponent q of the power law mass distribution of bodies must be greater than two during all the planetary formation process. However, if during oligarchic growth a bimodal mass distribution of small and large bodies exists, the mass distribution of small bodies allows q less than 2 provided the mass ratio between the largest body of such distribution and the smallest body of the distribution of large planetesimals is smaller than  0.1-0.01.& 2012ElsevierLtd.Allrightsreserved.