172 research outputs found
Testing and Resilience of the Impact Origin of the Moon
The leading hypothesis for the origin of the Moon is the giant impact model, which grew out of the post-Apollo science community. The hypothesis was able to explain the high E-M system angular momentum, the small lunar core, and consistent with the idea that the early Moon melted substantially. The standard hypothesis requires that the Moon be made entirely from the impactor, strangely at odds with the nearly identical oxygen isotopic composition of the Earth and Moon, compositions that might be expected to be different if Moon came from a distinct impactor. Subsequent geochemical research has highlighted the similarity of both geochemical and isotopic composition of the Earth and Moon, and measured small but significant amounts of volatiles in lunar glassy materials, both of which are seemingly at odds with the standard giant impact model. Here we focus on key geochemical measurements and spacecraft observations that have prompted a healthy re-evaluation of the giant impact model, provide an overview of physical models that are either newly proposed or slightly revised from previous ideas, to explain the new datasets
Habitable Planet Formation in Binary-Planetary Systems
Recent radial velocity observations have indicated that Jovian-type planets
can exist in moderately close binary star systems. Numerical simulations of the
dynamical stability of terrestrial-class planets in such environments have
shown that, in addition to their giant planets, these systems can also harbor
Earth-like objects. In this paper, we study the late stage of terrestrial
planet formation in such binary-planetary systems, and present the results of
the simulations of the formation of Earth-like bodies in their habitable zones.
We consider a circumprimary disk of Moon- to Mars-sized objects and numerically
integrate the orbits of these bodies at the presence of the Jovian-type planet
of the system and for different values of the mass, semimajor axis, and orbital
eccentricity of the secondary star. Results indicate that, Earth-like objects,
with substantial amounts of water, can form in the habitable zone of the
primary star. Simulations also indicate that, by transferring angular momentum
from the secondary star to protoplanetary objects, the giant planet of the
system plays a key role in the radial mixing of these bodies and the water
contents of the final terrestrial planets. We will discuss the results of our
simulation and show that the formation of habitable planets in binary-planetary
systems is more probable in binaries with moderate to large perihelia.Comment: 27 pages, 11 figures, submitted for publicatio
The potential for tidally heated icy and temperate moons around exoplanets
Moons of giant planets may represent an alternative to the classical picture
of habitable worlds. They may exist within the circumstellar habitable zone of
a parent star, and through tidal energy dissipation they may also offer
alternative habitable zones, where stellar insolation plays a secondary, or
complementary, role. We investigate the potential extent of stable satellite
orbits around a set of 74 known extrasolar giant planets located beyond 0.6 AU
from their parent stars - where moons should be long-lived with respect to
removal by stellar tides. Approximately 60% of these giant planets can sustain
satellites or moons in bands up to AU in width. For comparison, the
Galiean satellites extend to AU. We investigate the stellar
insolation that moons would experience for these exoplanet systems, and the
implications for sublimation loss of volatiles. We find that between 15 and 27%
of {\em all} known exoplanets may be capable of harboring small, icy, moons. In
addition, some 22-28% of all known exoplanets could harbor moons within a
``sublimation zone'', with insolation temperatures between 273 K and 170 K. A
simplified energy balance model is applied to the situation of temperate moons,
maintained by a combination of stellar insolation and tidal heat flow. We
demonstrate that large moons (M), at orbital radii
commensurate with those of the Galilean satellites, could maintain temperate,
or habitable, surface conditions during episodes of tidal heat dissipation of
the order 1-100 times that currently seen on Io. (Abridged).Comment: 28 pages, 8 Figures, AASTex, Accepted for publication in the
Astrophysical Journa
Debris discs in the 27 Myr old open cluster IC4665
We present Spitzer IRAC and MIPS 24um imaging of members of the 27+/-5Myr old
open cluster IC 4665. Models for the assembly of terrestrial planets through
planetesimal collisions and mergers predict episodic dust debris discs at this
epoch. We determine that 42(+18-13)% of the solar-type (F5-K5) cluster members
have excess emission at 24um indicative of these debris discs, the highest
frequency of the clusters studied with Spitzer to date. The majority of these
discs have intermediate levels of excess (F_24/F_phot < 2), and no source is
found to have extreme levels of excess indicative of a recent transient event
as opposed to steady-state collisional evolution. We find no evidence of a link
between multiplicity and 24um excess in this cluster sample. Only the
early-type star TYC424-473-1 (T_eff~8420K) has significant near-infrared excess
from 4.5um as measured with IRAC. Two solar-type targets have low significance
8um excess but no significant 24um excess. All other targets show no evidence
for near-infrared excess which could indicate the presence of an optically
thick primordial disc, demonstrating that the observed 24um excess arises from
a debris disc.Comment: 14 pages, 11 figures, accepted for publication in MNRA
Origin and Evolution of Saturn's Ring System
The origin and long-term evolution of Saturn's rings is still an unsolved
problem in modern planetary science. In this chapter we review the current
state of our knowledge on this long-standing question for the main rings (A,
Cassini Division, B, C), the F Ring, and the diffuse rings (E and G). During
the Voyager era, models of evolutionary processes affecting the rings on long
time scales (erosion, viscous spreading, accretion, ballistic transport, etc.)
had suggested that Saturn's rings are not older than 100 My. In addition,
Saturn's large system of diffuse rings has been thought to be the result of
material loss from one or more of Saturn's satellites. In the Cassini era, high
spatial and spectral resolution data have allowed progress to be made on some
of these questions. Discoveries such as the ''propellers'' in the A ring, the
shape of ring-embedded moonlets, the clumps in the F Ring, and Enceladus' plume
provide new constraints on evolutionary processes in Saturn's rings. At the
same time, advances in numerical simulations over the last 20 years have opened
the way to realistic models of the rings's fine scale structure, and progress
in our understanding of the formation of the Solar System provides a
better-defined historical context in which to understand ring formation. All
these elements have important implications for the origin and long-term
evolution of Saturn's rings. They strengthen the idea that Saturn's rings are
very dynamical and rapidly evolving, while new arguments suggest that the rings
could be older than previously believed, provided that they are regularly
renewed. Key evolutionary processes, timescales and possible scenarios for the
rings's origin are reviewed in the light of tComment: Chapter 17 of the book ''Saturn After Cassini-Huygens'' Saturn from
Cassini-Huygens, Dougherty, M.K.; Esposito, L.W.; Krimigis, S.M. (Ed.) (2009)
537-57
Rings in the Solar System: a short review
Rings are ubiquitous around giant planets in our Solar System. They evolve
jointly with the nearby satellite system. They could form either during the
giant planet formation process or much later, as a result of large scale
dynamical instabilities either in the local satellite system, or at the
planetary scale. We review here the main characteristics of rings in our solar
system, and discuss their main evolution processes and possible origin. We also
discuss the recent discovery of rings around small bodies.Comment: Accepted for the Handbook of Exoplanet
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