Moonlets in Dense Planetary Rings

doi:10.1017/9781316286791.008

8 - Moonlets in Dense Planetary Rings

from III - Ring Systems by Type and Topic

Published online by Cambridge University Press: 26 February 2018

F. Spahn ,

H. Hoffmann ,

H. Rein ,

M. Seiss ,

M. Sremčević and

M.S. Tiscareno

Edited by

Matthew S. Tiscareno and

Carl D. Murray

Show author details

F. Spahn: Affiliation:
University of Potsdam Potsdam, GERMANY
H. Hoffmann: Affiliation:
University of Potsdam Potsdam, GERMANY
H. Rein: Affiliation:
University of Toronto Toronto, Ontario, CANADA
M. Seiss: Affiliation:
University of Potsdam Potsdam, GERMANY
M. Sremčević: Affiliation:
University of Colorado Boulder, Colorado, USA
M.S. Tiscareno: Affiliation:
SETI Institute Mountain View, California, USA
Matthew S. Tiscareno: Affiliation:
SETI Institute, California
Carl D. Murray: Affiliation:
Queen Mary University of London

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Summary

INTRODUCTION

When, in 1610, Galileo Galilei directed his telescope at Saturn, he discovered some puzzling addenda on either side of that planet, changing their appearance over the course of a few years – and even more disturbing, at certain instants they seemed to disappear and then return. These appendages remained a scientific riddle for about half a century until Christian Huygens came up with a seemingly correct model – he proposed that a solid ring is girdling Saturn. In 1675, G. D. Cassini's detection of a division in Saturn's rings – the Cassini Division separating the outer A and inner B rings – questioned Huygens’ hypothesis of a solid ring.

Almost 200 years later, in his famous work, Maxwell (1859) proved that a solid ring cannot be a stable configuration, suggesting instead that a myriad of individual tiny satellites form the rings of Saturn. This theoretical prediction was later confirmed experimentally by J. E. Keeler, who measured Doppler frequency shifts on either side of Saturn's rings (Keeler, 1889, 1895), showing that individual ring particles encircle Saturn at Kepler speeds.

Since those studies in the nineteenth century, the mesoscopic particulate nature of Saturn's rings has been widely accepted. Since the prediction of a flat monolayer ring by Jeffreys (1947), mainly suggested by the frequent inelastic collisions among the ring particles, only a little has been said about the properties of ring particles themselves – their size distribution, composition, etc., and their evolution as a granular ensemble.

Hénon (1981), motivated by the Pioneer and Voyager space missions to the outer solar system in the late 1970s and early 1980s, assumed a broad size distribution of the ring particles in order to explain spacecraft observations of the dense rings of Saturn. Properties like the apparent thickness of the rings or the distribution of the widths of dilute or empty gaps have been addressed by an extended power-law to characterize the size distribution of the ring particles. The idea behind this approach is that, depending on its size, a ring particle (especially sub-kilometer or kilometer-sized boulders, hereafter called moonlets) should gravitationally carve density features in the surrounding ring matter.

Type: Chapter
Information: Planetary Ring Systems
Properties, Structure, and Evolution
, pp. 157 - 197

DOI: https://doi.org/10.1017/9781316286791.008 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2018

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References

Abramowitz, M., and Stegun, I. A. 1970. Handbook of Mathematical Functions. Dover Publications, NY. Albers, N. 2006. On the relevance of particle adhesion: Applications to Saturn's rings. Ph. D. thesis, Universitat Potsdam.Google Scholar

Albers, N., and Spahn, F. 2006. The influence of particle adhesion on the stability of agglomerates in Saturn's rings. Icarus, 181, 292-301.CrossRef Google Scholar

Araki, S. 1988. The dynamics of particle disks. II —Effects of spin degrees of freedom. Icarus, 76, 182-198.CrossRef Google Scholar

Araki, S., and Tremaine, S. 1986. The dynamics of dense particle disks. Icarus, 65, 83-109.CrossRef Google Scholar

Baillie, K., Colwell, J. E., Esposito, L. W., and Lewis, M. C. 2013. Meter-sized moonlet population in Saturn's C ring and Cassini Division. AJ, 145, 171.CrossRef Google Scholar

Barnes, J., and Hut, P. 1986. A hierarchical O(N log N) force-calculation algorithm. Nature, 324, 446—449.Google Scholar

Beurle, K., Murray, C. D., Williams, G. A., et al. 2010. Direct evidence for gravitational instability and moonlet formation in Saturn's rings. AJ, 718, L176-L180.Google Scholar

Bodrova, A., Schmidt, J., Spahn, E., and Brilliantov, N. 2012. Adhesion and collisional release of particles in dense planetary rings. Icarus, 218, 60-68.CrossRef Google Scholar

Bodrova, A., Levchenko, D., and Brilliantov, N. 2014. Universality of temperature distribution in granular gas mixtures with a steep particle size distribution. EPL, 106, 14001.CrossRef Google Scholar

Borderies, N. 1989. Ring dynamics. Celestial Mechanics and Dynamical Astronomy, 46, 207-230.CrossRef Google Scholar

Borderies, N., Goldreich, P., and Tremaine, S. 1982. Sharp edges of planetary rings. Nature, 299, 209-211.CrossRef Google Scholar

Borderies, N., Goldreich, P., and Tremaine, S. 1983. Perturbed particle disks. Icarus, 55, 124-132.CrossRef Google Scholar

Borderies, N., Goldreich, P., and Tremaine, S. 1985. A granular flow model for dense planetary rings. Icarus, 63, 406-420.CrossRef Google Scholar

Borderies, N., Goldreich, P., and Tremaine, S. 1989. The formation of sharp edges in planetary rings by nearby satellites. Icarus, 80, 344-360.CrossRef Google Scholar

Bridges, F. G., Hatzes, A., and Lin, D. N. C. 1984. Structure, stability and evolution of Saturn's rings. Nature, 309, 333-335.CrossRef Google Scholar

Brilliantov, N. V., and Poschel, T. 2000a. Deviation from Maxwell distribution in granular gases with constant restitution coefficient. Phys. Rev. E, 61, 2809.CrossRef Google Scholar

Brilliantov, N. V., and Poschel, T. 2000b. Velocity distribution in granular gases of viscoelastic particles. Phys. Rev. E, 61, 5573.CrossRef Google Scholar

Brilliantov, N. V., Spahn, E., Hertzsch, J. -M., and Poschel, T. 1996. Model for collisions in granular gases. Phys. Rev. E, 53, 5382—5392.CrossRef Google Scholar PubMed

Brilliantov, N. V., Albers, N., Spahn, E., and Poschel, T. 2007. Collision dynamics of granular particles with adhesion. Phys. Rev. E, 76, 051302.CrossRef Google Scholar PubMed

Brilliantov, N. V., Krapivsky, P. L., Bodrova, A., et al. 2015. Size distribution of particles in Saturn s rings from aggregation and fragmentation. PNAS, 112, 9536-9541.CrossRef Google Scholar

Burns, J. A., and Cuzzi, J. N. C. 2006. Our local astrophysical laboratory. Science, 312, 1753-1755.CrossRef Google Scholar PubMed

Canup, R. M. 2010. Origin of Saturn's rings and inner moons by mass removal from a lost Titan-sized satellite. Nature, 468, 943-946.CrossRef Google Scholar PubMed

Charnoz, S., Brahic, A., Thomas, P. C., and Porco, C. C. 2007. The equatorial ridges of Pan and Atlas: Terminal accretionary ornaments? Science, 318, 1622-1624.CrossRef Google Scholar PubMed

Charnoz, S., Morbidelli, A., Dones, L., and Salmon, J. 2009. Did Saturn's rings form during the Late Heavy Bombardment? Icarus, 199, 413-28.CrossRef Google Scholar

Charnoz, S., Salmon, J., and Crida, A. 2010. The recent formation of Saturn's moonlets from viscous spreading of the main rings. Nature, 465, 752-754.CrossRef Google Scholar PubMed

Colwell, J. E., Nicholson, P. D., Tiscareno, M. S., et al. 2009. The structure of Saturn's rings. Page 375 of: Dougherty, M. K., Esposito, L. W., and Krimigis, S. M. (eds.), Saturn from Cassini-Huygens. Springer.Google Scholar

Crida, A., Papaloizou, J. C. B., Rein, H., Charnoz, S., and Salmon, J. 2010. Migration of a moonlet in a ring of solid particles: Theory and application to Saturn's propellers. AJ, 140, 944-953.CrossRef Google Scholar

Cuzzi, J. N., and Scargle, J. D. 1985. Wavy edges suggest moonlet in Encke's gap. ApJ, 292, 276-290.CrossRef Google Scholar

Daisaka, H., Tanaka, H., and Ida, S. 2001. Viscosity in a dense planetary ring with self-gravitating particles. Icarus, 154, 296—312.CrossRef Google Scholar

Dermott, S. E., and Murray, C. D. 1981. The dynamics of tadpole and horseshoe orbits. I -Theory. II -The coorbital satellites of Saturn. Icarus, 48, 1-22.CrossRef Google Scholar

Dermott, S. E., Murray, C. D., and Sinclair, A. T. 1980. The narrow rings of Jupiter, Saturn and Uranus. Nature, 284, 309—313.CrossRef Google Scholar

Dones, L. 1991. A recent cometary origin for Saturn's rings? Icarus, 92, 194-203.CrossRef Google Scholar

Dones, L., Cuzzi, J. N., and Showalter, M. R. 1993. Voyager Photometry of Saturn's A ring. Icarus, 105, 184—215.CrossRef Google Scholar

Esposito, L. W., Albers, N., Meinke, B. K., et al. 2012. A predator-prey model for moon-triggered clumping in Saturn's rings. Icarus, 217, 103-114.CrossRef Google Scholar

Flynn, B. C., and Cuzzi, J. N. 1989. Regular structure in the inner Cassini Division of Saturn's rings. Icarus, 82, 180—199.CrossRef Google Scholar

Goldreich, P., and Tremaine, S. 1978a. The excitation and evolution of density waves. ApJ, 222, 850-858.CrossRef Google Scholar

Goldreich, P., and Tremaine, S. D. 1978b. The formation of the Cassini division in Saturn's rings. Icarus, 34, 240—253.CrossRef Google Scholar

Goldreich, P., and Tremaine, S. D. 1978c. The velocity dispersion in Saturn's rings. Icarus, 34, 227-239.CrossRef Google Scholar

Goldreich, P., and Tremaine, S. 1979. Towards a theory for the Uranian rings. Nature, 277, 97-99.CrossRef Google Scholar

Goldreich, P., and Tremaine, S. 1982. The dynamics of planetary rings. ARA&A, 20, 249-283.Google Scholar

Guimaraes, A. H. E., Albers, N., Spahn, E., et al. 2012. Aggregates in the strength and gravity regine: Particle sizes in Saturn's rings. Icarus, 220, 660-678.CrossRef Google Scholar

Hameen-Anttila, K. A., and Lukkari, J. 1980. Numerical simulations of collisions in Keplerian systems. Ap&SS, 71, 475—497.Google Scholar

Hameen-Anttila, K. A., and Salo, H. 1993. Generalized theory of impacts in particulate systems. Earth Moon and Planets, 62, 47-84.CrossRef Google Scholar

Hedman, M. M., and Nicholson, P. D. 2014. More Kronoseismology with Saturn's rings. MNRAS, 444(Oct), 1369-1388.

Hedman, M. M., and Nicholson, P. D. 2016. The B-ring's surface mass density from hidden density waves: Less than meets the eye? Icarus, 279, 109-124.

Hedman, M. M., Nicholson, P. D., Salo, H., et al. 2007. Self-gravity wake structures in Saturn's A ring revealed by Cassini VIMS. AJ, 133, 2624-2629.CrossRef Google Scholar

Hedman, M. M., Nicholson, P. D., Baines, K. H., et al. 2010. The Architecture of the Cassini Division. AJ, 139, 228-251.CrossRef Google Scholar

Hedman, M. M., Nicholson, P. D., Cuzzi, J. N., et al. 2013. Connections between spectra and structure in Saturn's main rings based on Cassini VIMS data. Icarus, 223, 105-130.CrossRef Google Scholar

Henon, M. 1981. A simple model of Saturn's rings. Nature, 293, 33-35.CrossRef Google Scholar

Henon, M., and Petit, J. -M. 1986. Series expansion for encounter-type solutions of Hill's problem. Celestial Mechanics, 38, 67—100.CrossRef Google Scholar

Hertzsch, J. -M., Scholl, H., Spahn, E., and Katzorke, I. 1997. Simulation of collisions in planetary rings. A&A, 320, 319-324.Google Scholar

Hoffmann, H., SeiB, M., and Spahn, E. 2013. Vertical Relaxation of a Moonlet Propeller in Saturn's A Ring. ApJ, 765, L4.CrossRef Google Scholar

Hoffmann, H., SeiB, M., Salo, H., and Spahn, E. 2015. Vertical structures induced by embedded moonlets in Saturn's rings. Icarus, 252, 400-414.CrossRef Google Scholar

Horn, L. J., Showalter, M. R., and Russell, C. T. 1996. Detection and behavior of Pan wakes in Saturn's A ring. Icarus, 124, 663-676.CrossRef Google Scholar

Jacobson, R. A. 2014. The small Saturnian satellites —chaos and conundrum. Page 304. 05 of: AAS/Division of Dynamical Astronomy Meeting. AAS/Division of Dynamical Astronomy Meeting, vol. 45.Google Scholar

Jacobson, R. A., Spitale, J., Porco, C. C., et al. 2008. Revised orbits of Saturn's small inner satellites. AJ, 135, 261—263.CrossRef Google Scholar

Jeffreys, H. 1947. The effects of collisions on Saturn's rings. MNRAS, 107, 263.CrossRef Google Scholar

Julian, W. H., and Toomre, A. 1966. Non-axisymmetric responses of differentially rotating disks of stars. ApJ, 146, 810.CrossRef Google Scholar

Keeler, J. E. 1889. The outer ring of Saturn. AJ, 8, 175-175.CrossRef Google Scholar

Keeler, J. E. 1895. A spectroscopic proof of the meteoric constitution of Saturn's rings. ApJ, 1, 416.CrossRef Google Scholar

Lawney, B. P., Jenkins, J. T., and Burns, J. A. 2012. Collisional features in a model of a planetary ring. Icarus, 220, 383—391.CrossRef Google Scholar

Lee, V., Waitukaitis, S. R., Miskin, M. Z., and Jaeger, H. M. 2015. Direct observation of particle interactions and clustering in charged granular streams. Nature Physics, 11, 733-737.CrossRef Google Scholar

Lewis, M. C., and Stewart, G. R. 2000. Collisional dynamics of perturbed planetary rings. I. AJ, 120, 3295-3310.CrossRef Google Scholar

Lewis, M. C., and Stewart, G. R. 2005. Expectations for Cassini observations of ring material with nearby moons. Icarus, 178, 124-143.CrossRef Google Scholar

Lewis, M. C., and Stewart, G. R. 2009. Features around embedded moonlets in Saturn's rings: The role of self-gravity and particle size distributions. Icarus, 199, 387-412.CrossRef Google Scholar

Lissauer, J. J., Shu, F. H., and Cuzzi, J. N. 1981. Moonlets in Saturn's rings. Nature, 292, 707-711.CrossRef Google Scholar

Marouf, E. A., and Tyler, G. L. 1986. Detection of two satellites in the Cassini division of Saturn's rings. Nature, 323, 31—35.CrossRef Google Scholar

Maxwell, J. C. 1859. On the Stability of the Motion of Saturn's Rings. Cambridge and London: MacMillan and Co.Google Scholar

Michikoshi, S., and Kokubo, E. 2011. Formation of a propeller structure by a moonlet in a dense planetary ring. ApJ, 732, L23.CrossRef Google Scholar

Moons, M., Delhaise, E., and Depaepe, E. 1988. Elliptical Hill's problem (large and small impact parameters). Celestial Mechanics, 43, 349-359.Google Scholar

Murray, C. D., Beurle, K., Cooper, N. J., et al. 2008. The determination of the structure of Saturn's F ring by nearby moonlets. Nature, 453, 739-744.CrossRef Google Scholar PubMed

Murray, C. D., Cooper, N. J., Williams, G. A., Attree, N. O., and Boyer, J. S. 2014. The discovery and dynamical evolution of an object at the outer edge of Saturn's A ring. Icarus, 236, 165—168.CrossRef Google Scholar

Pan, M., and Chiang, E. 2010. The propeller and the frog. ApJ, 722, L178-L182.CrossRef Google Scholar

Pan, M., and Chiang, E. 2012. Care and feeding of frogs. AJ, 143, 9.CrossRef Google Scholar

Pan, M., Rein, H., Chiang, E., and Evans, S. N. 2012. Stochastic flights of propellers. MNRAS, 427, 2788-2796.CrossRef Google Scholar

Petit, J. -M., and Henon, M. 1987a. A numerical simulation of planetary rings. I -Binary encounters. A&A, 173, 389-404.Google Scholar

Petit, J. -M., and Henon, M. 1987b. A numerical simulation of planetary rings. II -Monte Carlo model. A&A, 188, 198-205.Google Scholar

Petit, J. -M., and Henon, M. 1988. A numerical simulation of plan-etary rings. Ill —Mass segregation, ring confinement, and gap formation. A&A, 199, 343-356.Google Scholar

Porco, C. C., Baker, E., Barbara, J., et al. 2005. Cassini imaging science: Initial results on Saturn's rings and small satellites. Science, 307, 1226-1236.Google Scholar PubMed

Porco, C. C., Thomas, P. C., Weiss, J. W., and Richardson, D. C. 2007. Saturn's small inner satellites: Clues to their origins. Science, 318, 1602.CrossRef Google Scholar PubMed

Rein, H., and Liu, S. -F. 2012. REBOUND: an open-source multi-purpose N-body code for collisional dynamics. A&A, 537, A128.Google Scholar

Rein, H., and Papaloizou, J. C. B. 2010. Stochastic orbital migration of small bodies in Saturn's rings. A&A, 524, A22.Google Scholar

Rein, H., and Tamayo, D. 2015. WHFAST: a fast and unbiased implementation of a symplectic Wisdom-Holman integrator for long-term gravitational simulations. MNRAS, 452, 376—388.CrossRef Google Scholar

Rein, H., and Tremaine, S. 2011. Symplectic integrators in the shearing sheet. MNRAS, 415, 3168-3176.CrossRef Google Scholar

Resibois, P., and De Leener, M. 1977. Classical Kinetic Theory of Fluids. Wiley & Sons, New York.Google Scholar

Richardson, D. C. 1994. Tree code simulations of planetary rings. MNRAS, 269, 493-511.CrossRef Google Scholar

Salo, H. 1991. Numerical simulations of dense collisional systems. Icarus, 90, 254-270.CrossRef Google Scholar

Salo, H. 1992a. Gravitational wakes in Saturn's rings. Nature, 359, 619-621.CrossRef Google Scholar

Salo, H. 1992b. Numerical simulations of dense collisional systems. II —Extended distribution of particle sizes. Icarus, 96, 85—106.CrossRef Google Scholar

Salo, H. 1995. Simulations of dense planetary rings. III. Self-gravitating identical particles. Icarus, 111, 287-312.Google Scholar

Salo, H., and Schmidt, J. 2010. N-body simulations of viscous instability of planetary rings. Icarus, 206, 390-09.CrossRef Google Scholar

Salo, H., Schmidt, J., and Spahn, F. 2001. Viscous overstability in Saturn's Bring. I. Direct simulations and measurement of transport coefficients. Icarus, 153, 295-315.CrossRef Google Scholar

Schmidt, J., and Salo, H. 2003. Weakly nonlinear model for oscillatory instability in Saturn's dense rings. Phys. Rev. Lett, 90, 061102.CrossRef Google Scholar PubMed

Schmidt, J., Salo, H., Petzschmann, O., and Spahn, F. 1999. Vertical distribution of temperature and density in a planetary ring. A&A, 345, 646-652.Google Scholar

Schmidt, J., Salo, H., Spahn, E., and Petzschmann, O. 2001. Viscous overstability in Saturn's B-ring. II. Hydrodynamic theory and comparison to simulations. Icarus, 153, 316-331.CrossRef Google Scholar

Schmidt, J., Ohtsuki, K., Rappaport, N., Salo, H., and Spahn, F. 2009. Dynamics of Saturn's dense rings. Pages 413—458 of: Dougherty, M. K., Esposito, L. W., and Krimigis, S. M. (eds.), Saturn from Cassini-Huygens. Springer.Google Scholar

Seiler, M., Sremčević, M., SeiB, M., Hoffmann, H., and Spahn, F. 2017. A librational model for the propellor Bleriot in the Saturnian ring system. Astrophys. J. Lett., 840, L16.Google Scholar

SeiB, M., and Spahn, F. 2011. Hydrodynamics of Saturn's dense rings. Mathematical Modelling of Natural Phenomena, 6(04), 191-218.

SeiB, M., Spahn, E., Sremčević, M., and Salo, H. 2005. Structures induced by small moonlets in Saturn's rings: Implications for the Cassini Mission. Geophy. Research Letters, 32, 11205.Google Scholar

SeiB, M., Spahn, E., and Schmidt, J. 2010. Moonlet induced wakes in planetary rings: Analytical model including eccentric orbits of moon and ring particles. Icarus, 210, 298-317.Google Scholar

Showalter, M. R. 1991. Visual detection of 1981S13, Saturn's eighteenth satellite, and its role in the Encke gap. Nature, 351, 709-713.CrossRef Google Scholar

Showalter, M. R., Cuzzi, J. N., Marouf, E. A., and Esposito, L. W. 1986. Satellite ‘wakes’ and the orbit of the Encke Gap moonlet. Icarus, 66, 297-323.CrossRef Google Scholar

Shu, F. H., Cuzzi, J. N., and Lissauer, J. J. 1983. Bending waves in Saturn's rings. Icarus, 53, 185—206.CrossRef Google Scholar

Shu, F. H., Yuan, C., and Lissauer, J. J. 1985a. Nonlinear spiral density waves -an inviscid theory. ApJ, 291, 356-376.CrossRef Google Scholar

Shu, F. H., Dones, L., Lissauer, J. J., Yuan, C., and Cuzzi, J. N. 1985b. Nonlinear spiral density waves —Viscous damping. ApJ, 299, 542-573.CrossRef Google Scholar

Simon, V., and Jenkins, J. T. 1994. On the vertical structure of dilute planetary rings. Icarus, 110, 109-116.CrossRef Google Scholar

Spahn, F. 1987. Scattering properties of a moonlet (satellite) embedded in a particle ring -Application to the rings of Saturn. Icarus, 71, 69-77.CrossRef Google Scholar

Spahn, R., and SeiB, M. 2015. Granular matter: Charges dropped. Nature Physics, 11, 709-710.CrossRef Google Scholar

Spahn, P., and Sponholz, H. 1989. Existence of moonlets in Saturn's rings inferred from the optical depth profile. Nature, 339, 607.CrossRef Google Scholar

Spahn, R., and Sremčević, M. 2000. Density patterns induced by small moonlets in Saturn's rings? A&A, 358, 368—372.Google Scholar

Spahn, R., and Wiebicke, H. -J. 1989. Long-term gravitational influence of moonlets in planetary rings. Icarus, 77, 124-134.CrossRef Google Scholar

Spahn, R., Petit, J. -M., and Bendjoya, P. 1993. The gravitational influence of satellite Pan on the radial distribution of ring-particles in the region of the Encke-division in Saturn's A ring. Celestial Mechanics and Dynamical Astronomy, 57, 391-402.CrossRef Google Scholar

Spahn, R., Scholl, H., and Hertzsch, J. 1994. Structures in planetary rings caused by embedded moonlets. Icarus, 111, 514—535.CrossRef Google Scholar

Spahn, R., Schmidt, J., Petzschmann, O., and Salo, H. 2000. Note: Stability analysis of a Keplerian disk of granular grains: Influence of thermal diffusion. Icarus, 145, 657-660.CrossRef Google Scholar

Spahn, R., Albers, N., Sremčević, M., and Thornton, C. 2004. Kinetic description of coagulation and fragmentation in dilute granular particle ensembles. EPL (Europhysics Letters), 67, 545—551.CrossRef Google Scholar

Spahn, R., Vieira Neto, E., Guimaraes, A. H. R., Gorban, A. N., and Brilliantov, N. V. 2014. A statistical model of aggregate fragmentation. New Journal of Physics, 16, 013031.CrossRef Google Scholar

Spitale, J. N., and Hahn, J. M. 2016. The shape of Saturn's Huygens ringlet viewed by Cassini ISS. Icarus, 279(Nov.), 141-154.CrossRef Google Scholar

Spitale, J. N., and Porco, C. C. 2010. Detection of free unstable modes and massive bodies in Saturn's outer Bring. AJ, 140, 1747-1757.CrossRef Google Scholar

Spitale, J. N., and Tiscareno, M. 2012. Cassini images a propeller in Saturn's B-ring. AAS Division on Dynamical Astronomy Meeting Abstracts, 44, 414. 04.Google Scholar

Spitale, J. N., Jacobson, R. A., Porco, C. C., and Owen, Jr., W. M. 2006. The orbits of Saturn's small satellites derived from combined historic and Cassini imaging observations. AJ, 132, 692—710.CrossRef Google Scholar

Sremčević, M., Spahn, R., and Duschl, W. J. 2002. Density structures in perturbed thin cold discs. MNRAS, 337, 1139-1152.CrossRef Google Scholar

Sremčević, M., Schmidt, J., et al. 2007. A belt of moonlets in Saturn's A ring. Nature, 449, 1019-1021.CrossRef Google Scholar PubMed

Sremčević, M., Esposito, L. W., Colwell, J. E., and Albers, N. 2011a. Bring gray ghosts in Cassini UVIS occultations. Page 1616 of: EPSC-DPS Joint Meeting 2011.

Sremčević, M., Stewart, G., Albers, N., and Esposito, L. W. 2011b. Discovery of Bring propellers in Cassini UVIS and ISS. AGU Fall Meeting Abstracts, B1677.

Sremčević, M., Stewart, G. R., Albers, N., and Esposito, L. W. 2014. Propellers in Saturn's rings. European Planetary Science Congress 2014, EPSC Abstracts, Vol. 9, id. EPSC2014-633.

Stewart, G. R. 1991. Nonlinear satellite wakes in planetary rings. I -Phase-space kinematics. Icarus, 94, 436-450.CrossRef Google Scholar

Stewart, G. R., Lin, D. N. C., and Bodenheimer, P. 1984. Collision-induced transport processes in planetary rings. Pages 447—512 of: Greenberg, R., and Brahic, A. (eds.), Planetary Rings. Tucson Arizona: University of Arizona Press.Google Scholar

Tamayo, D., Triaud, A. H. M. J., Menou, K., and Rein, H. 2015. Dynamical stability of imaged planetary systems in formation: Application to HL Tau. ApJ, 805, 100.CrossRef Google Scholar

Tiscareno, M. S. 2013. A modified ‘Type I migration’ model for propeller moons in Saturn's rings. Planet. Space Sci., 11, 136-142.Google Scholar

Tiscareno, M. S. 2017. Propeller peregrinations: Ongoing observations of disk-embedded migration in Saturn's rings. Icarus, Submitted.

Tiscareno, M. S., Burns, J. A., Hedman, M. M., et al. 2006. 100-metre-diameter moonlets in Saturn's A ring from observations of ‘propeller’ structures. Nature, 440, 648-650.CrossRef Google Scholar PubMed

Tiscareno, M. S., Burns, J. A., Nicholson, P. D., Hedman, M. M., and Porco, C. C. 2007. Cassini imaging of Saturn's rings. II. A wavelet technique for analysis of density waves and other radial structure in the rings. Icarus, 189, 14-34.Google Scholar

Tiscareno, M. S., Burns, J. A., Hedman, M. M., and Porco, C. C. 2008. The population of propellers in Saturn's A ring. AJ, 135, 1083—1091.CrossRef Google Scholar

Tiscareno, M. S., Perrine, R. P., Richardson, D. C., et al. 2010a. An analytic parameterization of self-gravity wakes in Saturn's rings, with application to occultations and propellers. AJ, 139, 492-503.CrossRef Google Scholar

Tiscareno, M. S., Burns, J. A., Sremčević, M., et al. 2010b. Physical characteristics and non-Keplerian orbital motion of “propeller” moons embedded in Saturn's rings. ApJ, 718, L92-L96.CrossRef Google Scholar

Tiscareno, M. S., Hedman, M. M., Burns, J. A., and Castillo-Rogez, J. C. 2013a. Compositions and origins of outer planet systems: Insights from the Roche critical density. ApJ, 765, L28.CrossRef Google Scholar

Tiscareno, M. S., Hedman, M. M., Burns, J. A., Weiss, J. W., and Porco, C. C. 2013b. Probing the inner boundaries of Saturn's A ring with the Iapetus -1:0 nodal bending wave. Icarus, 224, 201-208.CrossRef Google Scholar

Ward, W. R. 1997. Protoplanet migration by nebula tides. Icarus, 126, 261-281.CrossRef Google Scholar

Weidenschilling, S. J., Chapman, C. R., Davis, D. R., and Greenberg, R. 1984. Ring particles -Collisional interactions and physical nature. Pages 367-415 of: Greenberg, R., and Brahic, A. (eds.), Planetary Rings. Tucson, Arizona: University of Arizona Press.Google Scholar

Weiss, J. W., Porco, C. C., and Tiscareno, M. S. 2009. Ring edge waves and the masses of nearby satellites. AJ, 138, 272—286.CrossRef Google Scholar

Wisdom, J., and Holman, M. 1991. Symplectic maps for the n-body problem. AJ, 102, 1528-1538.CrossRef Google Scholar

Wisdom, J., and Tremaine, S. 1988. Local simulations of planetary rings. AJ, 95, 925-940.CrossRef Google Scholar

Zebker, H. A., Marouf, E. A., and Tyler, G. L. 1985. Saturn's rings —Particle size distributions for thin layer model. Icarus, 64, 531—548.CrossRef Google Scholar

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