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IAA Transactions, No. 8, ``Celestial Mechanics'', 2002
Regularity and chaos for planetary orbits in binaries
D. Benest
Observatoire de Nice, Nice, France
1. Introduction
Cosmogonical theories as well as recent observations allow us to expect the
existence of planets around many stars other than the Sun; moreover, several
planets have been detected around one of the components in binaries, 16 Cyg B
or Gliese 86 A for example. On the other hand, double and multiple star systems
are established to be more numerous than single stars (such as the Sun), at
least in the solar neighborhood. We are then faced to the following dynamical
problem: assuming that planets can form in a binary early environment (we do
not deal here with, although observations have been made recently of which is
interpreted as protoplanetary disks, included in binary systems: BD+31 o 643 or
L1551 for example), does longterm stability for planetary orbits exist in double
star systems?
2. The model
The dynamical model is the elliptic plane restricted threebody problem; the
phase space of initial conditions for the planet of negligible mass (X o
, V o
) is
systematically explored for given physical parameters of the binary (the reduced
mass Ї of the `sun' of the planet and the orbital eccentricity e of the binary), and
limits for stability are established.
Previous papers showed that stable planetary orbits, around either the lightest
or the heaviest component of several nearby binary systems, exist up to distances
from their primary of the order of more than half the binary's periastron sep
aration. Moreover, among the stable planetary orbits found, in binary systems
where Ї = 0:45 for the lightest and 0.55 for the heaviest (and are nearly of solar
type), i.e. the ff Centauri (e = 0:52), j CrB (e = 0:28) and ADS 12033 (e = 0:83)
systems, nearly circular orbits (e 3 ! 0.1, and even e 3 ! 0.05, where e 3 is the
eccentricity of the planet around its `sun') lay inside the habitable zone -- as de
fined by Hart; but, in the ADS 11060 system, not any such nearly circular orbits
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were found; we may conjecture that the high eccentricity of this binary (0.96) is
at least one of the causes of this miss, although a verification is desirable.
The systematic study of stable planetary orbits in nearly binaries is to be
continued, the final goal being to establish the general rules of existence of such
orbits as function of the parameters Ї and e.
But our definition here of the stability is: an orbit is called stable if there has
been neither collision with a star nor escape during a given time, here chosen --
by a criterium depending on the computing time -- to 100 orbital revolutions of
the binary. Can we be sure that a longer integration will give the same result?
3. Chaos: bounded or sticky?
It is now wellknown that planetary dynamics may include some proportion of
chaos. During the previous studies, several indices have revealed that a difference
in the initial conditions, even as little as 10 \Gamma6 in X o , may induce in some cases an
orbital destiny completely different, not only at the border of the stability zone
but even inside this latter.
The next step is naturally the use of indicators of chaos (such as Lyapunov
coefficients or frequency analysis, for example) to try to determine, among the
stable orbits (stable in the sense defined above), how many are chaotic: are they all
chaotic, or does a `strong nucleus' of regular orbits remain? Note that, fortunately,
chaos does not always mean lethal destiny: we know for example that the orbit
of the Earth is chaotic, i.e. we cannot know the exact position and velocity of
the Earth over millenia, but this is `confined' chaos because the Earth orbit stays
inside a bounded region of the phase space. Nevertheless, an orbit may look like
such a confined chaos configuration during a very long time (up to several billions
years) and then blow up: such an orbit is called `sticky'.
This communication will present our latest results about the evolution during
long time spans of the orbital elements, together with the greatest Lyapunov
coefficient, for some fictitious planets orbiting a component of a binary.
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