We compute the strengths of zero-th order (in eccentricity) three-body
resonances for a co-planar and low eccentricity multiple planet system. In a
numerical integration we illustrate that slowly moving Laplace angles are
matched by variations in semi-major axes among three bodies with the outer two
bodies moving in the same direction and the inner one moving in the opposite
direction, as would be expected from the two quantities that are conserved in
the three-body resonance. A resonance overlap criterion is derived for the
closely and equally spaced, equal mass system with three-body resonances
overlapping when interplanetary separation is less than an order unity factor
times the planet mass to the one quarter power. We find that three-body
resonances are sufficiently dense to account for wander in semi-major axis seen
in numerical integrations of closely spaced systems and they are likely the
cause of instability of these systems. For interplanetary separations outside
the overlap region, stability timescales significantly increase. Crudely
estimated diffusion coefficients in eccentricity and semi-major axis depend on
a high power of planet mass and interplanetary spacing. An exponential
dependence previously fit to stability or crossing timescales is likely due to
the limited range of parameters and times possible in integration and the
strong power law dependence of the diffusion rates on these quantities.Comment: submitted to MNRA