Références

  • Bottke, W. F.; D. Durda; D. Nesvorny; R. Jedicke; A. Morbidelli; D. Vokrouhlicky and H. Levison, Linking the collisional history of the main asteroid belt to its dynamics excitation and depletion, Icarus, (2005).
  • Davis, D. R.; D. D. Durda; F. Marzari; A. Campo Bagatin and R. Gil-Hutton, Collisional Evolution of Small Body Populations, in Asteroids III,  W. F. Bottke, A. Cellino, P. Paolicchi and R. P. Binzel, eds. , Univ. of Arizona Press, Tucson, 2002, pp. 545-58.
  • Durda, D. D.; R. Greenberg and R. Jedicke, Collisional Models and scaling laws : A new interpretation of the shape of the main-belt asteroid size distribution, icarus, 135 (1998), pp. 431-40.
  • R. Gomes, H. F. Levison, K. Tsiganis, A. Morbidelli (2005). “Origin of the cataclysmic Late Heavy Bombardment period of the terrestrial planets” . Nature 435 (7041): 466–9
  • Hartmann, W. K., Terrestrial and Lunar Flux of large meteorites in the last two billion years, Icarus, 4 (1965), pp. 157-65
  • Hartmann, W. K., Martian cratering 8: Isochron refinement and the chronology of Mars, icarus, 174 (2005), pp. 294-320.
  • Ivanov, B. A., Mars/Moon cratering rate ratio estimates, Space Science Review, 96 (2001), pp. 87-104.
  • McEwen, A. S.; B. S. Preblich; E. P. Turtle; N. A. Artemieva; M. P. Golombek; M. Hurst; R. L. Kirk; D. M. Burr and P. R. Christensen, The rayed crater Zunil and interpretations of small impact craters on Mars, Icarus, in press (2005).
  • Neukum, G. and B. A. Ivanov, Crater size distribution and impact probabilities on Earth from Lunar, terrestrial-planet, and asteroid cratering data, in T. Gehrels, ed., Hasards due to Comets and Asteroids, Univ. Arizona Press, Tucson, 1994, pp. 359-416.
  • Neukum, G.; B. A. Ivanov and Hartmann W.K., Cratering records in the inner solar system in relation to the lunar reference system, space science review, 96 (2001), pp. 55-86.
  • Popova, O.; I. Nemtchinov and W. K. Hartmann, Bolides in the present and past Martian atmosphere and effects on cratering processes, Meteoritics and planetary science, 38 (2003), pp. 905-25.
  • Quantin, C.; P. Allemand; N. Mangold and C. Delacourt, Ages of Valles Marineris (Mars) landslides and implications for canyon history, Icarus, 172 (2004), pp. 555-72.
  • Quantin-Nataf, C. (2005a), Evolution géologique et climatique de Valles Marineris (Mars), Thèse de doctorat, Université Claude Bernard-Lyon 1.
  • Stöffler, D. and G. Ryder, Stratigraphy and isostope ages of the lunar geologic units : chronological standard for the inner solar system, space science review, 96 (2001), pp. 9-54.
  • Tanaka, K. L., the stratigraphy of Mars, Journal of Geophysical Research, 91 (1986), pp. 139-58.

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