Hostname: page-component-77c89778f8-m42fx Total loading time: 0 Render date: 2024-07-20T08:40:29.491Z Has data issue: false hasContentIssue false
  • English
  • Français

Statistical and Evolutionary Aspects of Cometary Orbits

Published online by Cambridge University Press:  12 April 2016

J.A. Fernández  and
W.-H. Ip
J.A. Fernández
Affiliation:
Departamento de Astronomia, Facultad de Humanidades y Ciencias Tristán Narvaja 1674, Montevideo, Uruguay
W.-H. Ip
Affiliation:
Max-Planck-Institut für Aeronomie D-3411 Katlenburg-Lindau, Federal Republic ofGermany

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

The observed frequency of passages of Earth-crossing long-period (LP) comets (P > 200 yr) is about three per year for comets brighter than absolute magnitude H10 ∼ 10.5. About one out of six LP comets is estimated to be new, i.e., making its first passage through the inner planetary region. The sample of observed LP comets shows an excess of retrograde orbits that may be accounted for by the shorter dynamical lifetimes of comets on direct orbits due to planetary perturbations. The original semimajor axes of new comets concentrate in the range 7 × 103aorig ≳ 4 × 104 AU, which tells us about the region of the Oort cloud where forces other than planetary perturbations act with the greatest efficiency. Yet the distribution of original semimajor axes cannot tell us anything about the existence of a dense inner core of the Oort cloud. Besides planetary perturbations, passing stars, molecular clouds and the galactic tidal force also influence the dynamical evolution of Oort cloud comets. The observed distribution of the aphelion points of near-parabolic comets shows such a dependence on the galactic latitude. Molecular clouds and stars penetrating very deeply in the Oort cloud are found to give rise to major enhancements in the influx rate of new comets, known as comet showers, at average intervals of a few 107 yr.

An important issue to solve concerns how the frequency of comet passages varies with time, in particular as regards to the current level of comet appearances. Should we be passing through a highly intense phase, most aphelia of the incoming Oort comets would concentrate on the sky area where the strong perturber exerted its greatest effect. By contrast, the observed galactic latitude dependence of the aphelia suggests a dominant influence of the vertical galactic tidal force as compared with random strong perturbers. This seems to indicate that the frequency of comet passages is currently at, or near, its quiescent level. Whether intense comet showers are reflected in the impact cratering record is still a debatable issue. A periodicity of ∼ 26-30 Myr in the impact cratering rate is quite uncertain, owing to the small size of the sample of well-dated craters and the noise from background impact craters from asteroids.

The family of short-period (SP) comets (orbital periods P < 20 yr) has long been regarded as the dynamical end-state of new comets on low-inclination orbits captured by Jupiter. However, if SP comets came from a spherical population of comets (e.g., incoming new comets), we should expect to find a percentage of them on retrograde orbits, which contradicts the observations. An alternative hypothesis for the origin of most SP comets is that they come from a trans-Neptunian comet belt. Extensive searches aimed at detecting faint slow-moving objects are required to assess the size of the comet population in the outer planetary region. Modeling of the transfer rate of comets from an outer belt to SP orbits gives transient populations between Saturn and Neptune on the order of 106 – 107 bodies. This is roughly comparable to the upper limit set by the most recent searches of outer solar system bodies.

The impact crater production rate of comets, at the present time, can be estimated to be on the order of 10% of the value corresponding to asteroidal impacts. These estimates, however, are subject to large uncertainties in the brightness-mass relation of comets and crater scaling law. The Earth could have received about 2 × 1020 g of cometary material over the last 4 billion years — if the injection rate of new comets remained constant in the time interval. Within the context of H2O inventory, the cometary influx should have rather minor effects. On the other hand, because of the paucity of H2O content in the atmospheres of Venus and Mars, cometary impact could strongly modulate their water contents.

Type
Section III: Comets, Origins, and Evolution
Information
International Astronomical Union Colloquium , Volume 116 , Issue 1: Comets in the Post-Halley Era , 1989 , pp. 487 - 535
Copyright
Copyright © Kluwer 1991

References

Allen, C.W. (1963) Astrophysical Quantities (second edition), Athlone Press, London, p.155.Google Scholar
Alvarez, L.W., Alvarez, W., Asaro, F., and Miches, H.V. (1980) “Extraterrestrial cause for the Cretaceous-Tertiary extinction,” Science 208, 10951108.Google Scholar
Alvarez, W., and Muller, R.A. (1984) “Evidence from crater ages for periodic impacts on the Earth,” Nature 308, 718720.Google Scholar
Antonov, V.A., and Latyshev, I.N. (1972) “Determination of the form of the Oort cometary cloud as the Hill surface in the galactic field,” in Chebotarev, G.A., Kazimirchak-Polonskaya, E.I. and Marsden, B.G. (eds.), The Motion, Evolution of Orbits, and Origin of Comets, IAU Symp. No. 45, Reidel, Dordrecht, Springer-Verlag, New York, pp. 341345.Google Scholar
Bahcall, J.N. (1984) “Self-consistent determination of the total amount of matter near the Sun,” Astrophys. J. 276, 169181.CrossRefGoogle Scholar
Bahcall, J.N., and Soneira, R.M. (1981) “The distribution of stars to V = 16th magnitude near the north galactic pole: Normalization, clustering properties, and counts in various bands,” Astrophys. J. 246, 122135.Google Scholar
Bailey, M.E. (1983) “The structure and evolution of the Solar System comet cloud,” Mon. Not. Roy. Astron. Soc. 204, 603633.CrossRefGoogle Scholar
Bailey, M.E. (1986) “The near-parabolic flux and the origin of short period comets,” Nature 324, 350352.Google Scholar
Bailey, M.E., and Stagg, C.R. (1988) “Cratering constraints on the inner Oort cloud; steady-state models,” Mon. Not. Roy. Astron. Soc. 235, 132.Google Scholar
Biermann, L. (1978) “Dense interstellar clouds and comets,” in Reiz, A. and Anderson, T. (eds.), Astronomical Papers Dedicated to Bengt Stromgren, Copenhagen Observatory, p. 327.Google Scholar
Biermann, L., Huebner, W.F., and Lust, R. (1983) “Aphelion clustering of ‘new’ comets: Star tracks through Oort’s cloud,” Proc. Natl. Acad. Sci. USA 80, 51515155.Google Scholar
Bilo, E.H., and van de Hulst, H.C. (1960) “Methods for computing the original orbits of comets,” Bull. Astron. Inst. Neth. 15, 119127.Google Scholar
Bogart, R.S., and Noerdlinger, P.D. (1982) “ On the distribution of orbits among long-period comets,” Astron. J. 87, 911917.CrossRefGoogle Scholar
Byl, J. (1983) “Galactic perturbations on near-parabolic cometary orbits,” Moon and Planets 29, 121137.Google Scholar
Cameron, A.G.W. (1962) “The formation of the Sun and the planets,” Icarus 1, 1369.Google Scholar
Carusi, A., Kresák, L., Perozzi, E., and Valsecchi, G.B. (1984) Long-Term Evolution of Short-Period Comets, Instituto Astrofísical Spaziale Internal Report 12 Rome.Google Scholar
Chebotarev, G.A. (1966) “Cometary motion in the outer solar system,” Soviet Astron. - AJ 10, 341344.Google Scholar
Chyba, C.F. (1987) “The cometary contribution to the oceans of primitive Earth,” Nature 330, 632635.Google Scholar
Cowan, J.J., and A’Hearn, M.F. (1979) “Vaporization of comet nuclei: Light curves and life times,” Moon and Planets 21, 155171.CrossRefGoogle Scholar
Davis, M., Hut, P., and Muller, R.A. (1984) “Extinction of species by periodic comet showers,” Nature 308, 715717.Google Scholar
Delsemme, A.H. (1973) “Origin of the short-period comets,” Astron Astrophys. 29, 377381.Google Scholar
Delsemme, A.H. (1986) “Cometary evidence for a solar companion?,” in Smoluchowski, R., Bahcall, J.N., and Matthews, M.S. (eds.), The Galaxy and the Solar System, Univ. of Arizona Press, Tucson, pp. 173203.Google Scholar
Delemme, A.H. (1989) “Whence come comets?,” Sky & Telese. March, 260-264.Google Scholar
Delemme, A.H., and Patmiou, M. (1986) “Galactic tides affect the Oort cloud: An observational confirmation,” in Proc. 20th ESLAB Symp. on the Exploration of Halley’s Comet, Heidelberg, ESA SP-250, pp. 409412.Google Scholar
Donahue, T.M., Hoffman, J.H., Hodges, R.R. Jr., and Watson, A.J. (1982) “Venus was wet: A measurement of the ratio of deuterium to hydrogen,” Science 216, 630633.Google Scholar
Donnison, J.R., and Sugden, R.A. (1984) “The distribution of asteroids diameters,” Mon. Not. Roy. Astron. Soc. 210, 673682.Google Scholar
Drapatz, S., and Zinnecker, H. (1984) “The size and mass distribution of Galactic molecular clouds,” Mon. Not. Roy. Astron. Soc. 210, llp14p.CrossRefGoogle Scholar
Duncan, M., Quinn, T., and Tremarne, S. (1987) “The formation and extent of the solar system comet cloud,” Astron. J. 94, 13301338.Google Scholar
Duncan, M., Quinn, T., and Tremarne, S. (1988) “The origin of short-period comets,” Astrophys. J. Letts. 328, L69L73.Google Scholar
Duncan, M., Quinn, T., and Tremarne, S. (1989) “The long-term evolution of orbits in the Solar System: A mapping approach,” CITA preprint.Google Scholar
Everhart, E. (1967) “Intrinsic distributions of cometary perihelia and magnitudes,” Astron. J. 72, 10021011.Google Scholar
Everhart, E. (1968) “Change in total energy of comets passing through the Solar System,” Astron. J. 73, 10391052.Google Scholar
Everhart, E. (1972) “The origin of short-period comets,” Astrophys. Lett. 10, 131135.Google Scholar
Everhart, E. (1976) “The evolution of comet orbits,” in Donn, B., Munna, M., Jackson, W., A’Hearn, M., and Harrington, R. (eds.), The Study of Comets, IAU Coll. No. 25, NASA SP-393, pp. 445464.Google Scholar
Everhart, E., and Marsden, B.G. (1983) “New original and future cometary orbits. III,” Astron. J. 93, 753754.Google Scholar
Fernández, J.A. (1980a) “Evolution of comet orbits under the perturbing influence of the giant planets and nearby stars,” Icarus 42, 406421.Google Scholar
Fernández, J.A. (1980b) “On the existence of a comet belt beyond Neptune,” Mon. Not. Roy. Astron. Soc. 192, 481491.Google Scholar
Fernández, J.A. (1981a) “New and evolved comets in the solar system,” Astron. Astrophys. 96, 2635.Google Scholar
Fernández, J.A. (1981b) “On the observed excess of retrograde orbits among long-period comets,” Mon. Not. Roy. Astron. Soc. 197, 265273.Google Scholar
Fernández, J.A. (1982) “Dynamical aspects of the origin of comets,” Astron. J. 87, 13181332.CrossRefGoogle Scholar
Fernández, J.A. (1985) “The formation and dynamical survival of the comet cloud,” Carusi, A. and Valsecchi, G.B. (eds.), Dynamics of Comets: Their Origin and Evolution, Reidel, Dordrecht, pp. 4570.CrossRefGoogle Scholar
Fernández, J.A. (1990) “Collisions of comets with meteoroids,” in Lagerkvist, C.-I., Rickman, H., Lindblad, B.A., and Lindgren, M. (eds.), Asteroids, Comets, Meteors III, University of Uppsala, pp. 309312.Google Scholar
Fernández, J.A., and Ip, W.-H. (1981) “Dynamical evolution of a cometary swarm in the outer planetary region,” Icarus 47, 470479.Google Scholar
Fernández, J.A., and Ip, W.-H. (1983a) “On the time evolution of the cometary influx in the region of the terrestrial planets,” Icarus 54, 377387.Google Scholar
Fernández, J.A., and Ip, W.-H. (1983b) “Dynamical origin of the short-period comets,” in Lagerkvist, C.-I. and Rickman, H. (eds.), Asteroids, Comets, Meteors, University of Uppsala, pp. 387390.Google Scholar
Fernández, J.A., and Ip, W.-H. (1987) “Time-dependent injection of Oort cloud comets into Earth-crossing orbits,” Icarus 71, 4656.Google Scholar
Fernández, J.A., and Jockers, K. (1983) “Nature and origin of comets,” Rep. Prog. Phys. 46, 665772.Google Scholar
Fesenkov, V.G. (1922) “Sur les perturbations séculaires dans le mouvement des cometes non péiodiques par des étoiles voisines,” Publ. Russian Astrophys. Obervatory 1, 186195.Google Scholar
Festou, M., Rickman, H., and Kamél, L. (1990) “The origin of nongravitational forces in cornets,” in Lagerkvist, C.-I., Rickman, H., Lindblad, B.A., and Lindgren, M. (eds.), Asteroids, Comets, Meteors III, University of Uppsala, pp. 313316.Google Scholar
Foog, M.J. (1989) “The relevance of the background impact flux to cyclic impact/mass extinction hypotheses,” Icarus 79, 382395.Google Scholar
Hamid, S.E., Marsken, B.G., and Whipple, F.L. (1968) “Influence of a comet belt beyond Neptune on the motions of periodic comets,” Astron. J. 73, 727729.Google Scholar
Hasegawa, I. (1976) “Distribution of the aphelia of long-period comets,” Publ. Astron. Soc. Japan 28, 259276.Google Scholar
Helin, E.F., and Shoemaker, E.M. (1979), “The Palomar planet-crossing asteroid survey 1973-1978,” Icarus 40, 321.Google Scholar
Heisler, J. and Tremarne, S. (1986) “The influence of the galactic tidal field on the Oort comet cloud,” Icarus 65, 1326.Google Scholar
Heisler, J. and Tremarne, S. (1989) “How dating uncertainties affect the detection of peri odicity in extinctions and craters,” Icarus 77, 213219.Google Scholar
Hills, J.G. (1981) “Comet showers and the steady-state infall of comets from the Oort cloud,” Astron. J. 86, 17301740.Google Scholar
Holsapple, K.A., and Schmidt, R.M. (1982) “On the scaling of crater dimensions 2, Impact processes,” J.Geophys. Res. 87, 18491870.Google Scholar
Hughes, D.W. (1982) “Astroidal size distribution,” Mon. Not. Roy. Astron. Soc. 199, 11491157.Google Scholar
Hughes, D.W. (1987) “Cometary magnitude distribution and the fading of comets,” Nature 325, 231232.Google Scholar
Hurnik, H. (1959) “The distribution of the directions of perihelia and the orbital poles of non-periodic comets,” Acta Astron. 9, 207221.Google Scholar
Hut, P., Alvarez, W., Hansen, T., Kauffman, E.G., Keller, G., Shoemaker, E.M. and Weissman, P.R. (1987) “Comet showers as a cause of mass extinctions,” Nature 329, 118126.Google Scholar
Hut, P., and Tremarne, S. (1985) “Have interstellar clouds disrupted the Oort comet cloud?,” Astron. J. 90, 15481557.Google Scholar
Ip, W.-H., and Fernández, J.A. (1988) “Exchange of condensed matter among the outer and terrestrial protoplanets and the effect on surface impact and atmospheric accretion,” Icarus 74, 4761.Google Scholar
Ip, W.-H., and Fernández, J.A. (1990) “Steady-state injection of short-period comets from the trans-Neptunian cometary belt,” submitted to Icarus.Google Scholar
Ishida, K., Mikami, T., and Kosai, H. (1984) “Size distribution of asteroids,” Publ. Astron. Soc. Japan 36, 357370.Google Scholar
Jackson, A.A., and Killen, R.M. (1988) “Infrared brightness of a comet belt beyond Neptune,” Earth, Moon, Planets 42, 4147.Google Scholar
Joss, P.C. (1973) “On the origin of short-period comets,” Astron. Astrophys. 25, 271273.Google Scholar
Kazimirchak-Polonskaya, E.I. (1976) “Review of investigations performed in the U.S.S.R. on close approaches of comets to Jupiter and the evolution of cometary orbits,” in Donn, B., Mumma, M., Jackson, W., A’Hearn, M., and Harrington, R. (eds.), The Study of Comets, NASA SP-393, pp. 490536.Google Scholar
Kowal, C.T. (1989) “A solar system survey,” Icarus 77, 118123.Google Scholar
Kresák, L. (1975) “The bias of the distribution of cometary orbits by observational selection,” Bull. Astron. Inst. Czech. 26, 92111.Google Scholar
Kresák, L. (1978) “The comet and asteroid population of the Earth’s environment,” Bull. Astron. Inst. Czech 29, 114125.Google Scholar
Kresák, L., and Pittich, E.M. (1978) “The intrinsic number density of active long-period comets in the inner solar system,” Bull. Astron. Inst. Czech 29, 299309.Google Scholar
Kuiper, G.P. (1951) “On the origin of the solar system,” in Hynek, J.A. (ed.), Astrophysics, McGraw-Hill, New York, pp. 357427.Google Scholar
Kumar, S., Hunten, D.M., and Pollack, J.B. (1983) “Nonthermal escape of hydrogen and deuterium from Venus and implication for loss of water,” Icarus 55, 369.Google Scholar
L”ust, R. (1984) “The distribution of the aphelion directions of long-period comets,” Astron. Astrophys. 141, 94100.Google Scholar
Luu, J.X., and Jewitt, D. (1988) “A two-part search for slow-moving objects,” Astron. J. 95, 12561262.Google Scholar
Marsden, B.G. (1986) Catalogue of Cometary Orbits, (fifth edition), IAU Central Bureau for Astron. Telegrams, Cambridge, Mass. Google Scholar
Marsden, B.G. (1990) “The sungrazing comet group. II,” Astron. J. (in press).CrossRefGoogle Scholar
Marsden, B.G., Sekanina, Z., and Everhart, E. (1978) “New osculating orbits for 110 comets and analysis of original orbits,” Astron. J. 83, 6471.CrossRefGoogle Scholar
Marsden, B.G., Sekanina, Z., and Yeomans, D.K. (1973) “Comets and nongravitational forces. V.,” Astron. J. 78, 211225.Google Scholar
McKinnon, W.B., and Mueller, S. (1988) “Pluto’s structure and composition suggest origin in the solar, not a planetary, nebula,” Nature 335, 240243.Google Scholar
Melosh, H.J. (1981) “Atmospheric breakup of terrestrial impactors,” in Schultz, P.H., and Merrill, R.B. (eds.), Multipling Basins, Proc. Lundar Planet Sci. 12A, pp 2935.Google Scholar
Mendis, D.A. (1973) “The comet-meteor stream complex,” Astrophys. Space Sci. 20, 165176.Google Scholar
Morris, D.E., and Muller, R.A. (1986) “Tidal gravitational forces: The infall of ‘new’ comets and comet showers,” Icarus 65, 112.Google Scholar
Napier, W.M., and Clube, S.V.M. (1979) “A theory of terrestrial catastrophism,” Nature 282, 455459.CrossRefGoogle Scholar
Napier, W.M., and Staniucha, M. (1982) “Interstellar planetesimals - I, Dissipation of a primordial cloud of comets by tidal encounters with massive nebulae,” Mon. Not. Roy., astron. Soc. 198, 723735.Google Scholar
Neukurn, G. (1975) “Mars: A standard crater curve and possible new time scale,” Science 194, 13811387.Google Scholar
Oja, H. (1975) “Perihelion distribution of near-parabolic comets,” Astron. Astrophys. 43, 317319.Google Scholar
Oort, J.H. (1950) “The structure of the cloud of comets surrounding the solar system and a hypothesis concerning its origin,” Bull. Astron. Inst. Neth. 11, 91110.Google Scholar
Öpik, E.J. (1932) “Note on stellar perturbations on nearly parabolic orbits,” Proc. Am. Acad. Arts. Sci. 67, 1659183.Google Scholar
Öpik, E.J. (1966) “Sun-grazing comets and tidal disruption,” Irish Astron. J. 7, 141161.Google Scholar
Owen, T., Maillard, J.P., de Bergh, C., and Lutz, B.L. (1988) “Deuterium on Mars: The abundance of HDO and the value of D/H,” Science 240, 17671769.Google Scholar
Porter, J.G. (1963) “The statistics of comet orbits,” in Middlehurst, B.M. and Kuiper, G.B. (eds.), The Moon, Meteorites and Comets, The University of Chicago Press, pp. 550572.Google Scholar
Pollack, J.B., and Yung, Y.L. (1980) “Origin and evolution of planetary atmospheres,” Ann. Rev. Earth Planet. Sci. 8, 425487.Google Scholar
Rampino, M.R., and Stothers, R.B. (1984) “Terrestrial mass extinctions, cometary impacts and the sun’s motion perpendicular to the galactic plane,” Nature 308, 709712.Google Scholar
Raup, D.M., and Sepkoski, J.J. (1984) “Periodicity of extinctions in the geologic past,” Proc. Natl. Acad. Sci. USA 81, 801805.Google Scholar
Rickman, H. (1976) “Stellar perturbations of orbits of long-period comets and their significance for cometary capture,” Bull. Astr. Inst. Czech. 27, 92105.Google Scholar
Rickman, H. (1986) “Masses and densities of comets Halley and Kopff,” in The Comet Nucleus Sample Return Mission Proc. Workshop, Canterbury, UK, ESA SP-249, pp. 195205.Google Scholar
Safranov, V.S. (1972) “Ejection of bodies from the solar system in the course of the accumulation of the giant planets and the formation of the cometary cloud,” in Chebotarev, G. A., Kazimirchak-Polonskaya, E.I. and Marsden, B.G. (eds.), The Motion, Evolution of Orbits, and Origin of Comets, I.A.U. Symp. No. 45, Reidel, Dordrecht, Springer-Verlag, New York, pp. 329334.Google Scholar
Sekanina, Z., and Yeomans, D.K. (1984) “Close encounters and collisions of comets with the Earth,” Astron. J. 89, 154161.Google Scholar
Shoemaker, E.M., Williams, J.G., Helin, E.F., and Wolfe, R.F. (1979) “Earth-crossing asteroids: orbital classes, collision rates with Earth, and origin,” in Asteroids, Gehrels, T. (ed.), Univ. of Arizona Press, Tucson, pp. 253.Google Scholar
Shoemaker, E.M., and Wolfe, R.F. (1982) “Cratering time scales for the Galilean satellites, in Satellites of Jupiter, Morrison, D. (ed.), Univ. of Arizona Press, Tucson, pp. 277339.Google Scholar
Smoluchowski, R., and Torbett, M. (1984) “The boundary of the solar system,” Nature 311, 3839.Google Scholar
Stagg, C.P., and Bailey, M.E. (1989) “Stochastic capture of short-period comets,” Mon. Not. Roy. Astron. Soc. 241, 507.Google Scholar
Stothers, R.B. (1984) “Mass extinctions and missing matter,” Nature 311, 17.Google Scholar
Stothers, R.B. (1988) “Structure of Oort’s comet cloud inferred from terrestrial impact craters,” The Observatory 108, 19.Google Scholar
Strom, R.G., and Neukum, G. (1988) “The cratering record on Mercury and the origin of impacting objects,” in Mercury, Eds. Vilas, F., Chapman, C.R. and Matthews, M.S., Univ. of Arizona Press, Tucson, 336373.Google Scholar
Talbot, R.J., and Newman, M.J. (1977) “Encounters between stars and dense interstellar clouds,” Astrophys. J. Suppl. Ser. 34, 295308.Google Scholar
Torbett, M.V. (1986) “Injection of Oort cloud comets to the inner solar system by galactic tidal fields,” Mon. Not. Roy. Astron. Soc. 223, 885895.Google Scholar
Tremarne, S. (1986) “Is there evidence for a solar companion star?,” in Smoluchowski, R., Bahcall, J.N., and Matthews, M.S. (eds.), The Galaxy and the Solar System, Univ. of Arizona Press, Tucson, pp. 409416.Google Scholar
Tyror, J.G. (1957) “The distribution of the directions of perihelia of long-period comets,” Mon. Not. Roy. Astron. Soc. 117, 369379.Google Scholar
van Woerkom, A.J.J. (1948) “On the origin of comets,” Bull. Astr. Inst. Neth. 10, 445472.Google Scholar
Wetherill, G.W. (1975) “Late heavy bombardment of the moon and terrestrial swarm sub sequent to the formation of the Earth and the Moon,” In Proc. 8th Lunar Sci. Coni., pp. 116.Google Scholar
Wetherill, G.W., and Shoemaker, E.M. (1982) “Collision of astronomically observable bodies with the Earth,” in Geological Implications of Impacts of Large Asteroids and Comets on the Earth, Geological Soc. Amer. Sp. Pap., 190, 1.Google Scholar
Weissman, P.R. (1980a) “Stellar perturbations of the cometary cloud,” Nature 288, 242243.Google Scholar
Weissman, P.R. (1980b) “Physical loss of long-period comets,” Astron. Astrophys. 85, 1919-196.Google Scholar
Weissman, P.R. (1983) “The mass of the Oort cloud,” Astron. Astrophys. 118, 9094.Google Scholar
Weissman, P.R. (1985a) “Dynamical evolution of the Oort cloud,” in Carusi, A. and Valsecchi, G.B. (eds.), Dynamics of Comets: Their Origin and Evolution, Reidel, Dordrecht, pp. 8796.Google Scholar
Weissman, P.R. (1985b) “Cometary dynamics,” Sp. Sci. Rev. 41, 299349.CrossRefGoogle Scholar
Weissman, P.R. (1985c) “Terrestrial impactors at geological boundary events: Comets or asteroids,” Nature 314, 517518.Google Scholar
Weissman, P.R. (1990) “The Oort cloud,” Nature (in press).Google Scholar
Whipple, F.L. (1950) “A comet model. I. The acceleration of comet Encke,” Astrophys. J. 1ll, 375394.Google Scholar
Whipple, F.L. (1964) “Evidence for a comet belt bezond Neptune,” Proc. Natl. Acad. Sci. 51, 711.Google Scholar
Whitmire, D.P., and Jackson, A.A. (1984) “Are periodic mass extinctions driven by a distant solar companion?,” Nature 308, 713715.Google Scholar
Yeomans, D.K., and Chodas, P.W. (1989) “An asymmetric outgassing model for cometary nongravitational accelerations,” Astron. J. 98, 10831093.Google Scholar