Abstract EN:

This thesis presents a study of the rotational properties of particles in Saturn's A and C rings. Their own rotation rate ω depends on relative speeds and on the surface quality of regolith. To constrain ω, we need to interpret the thermal emission of the dise (function of thermal inertia Γ and ω) according to the phase angle a and the longitude, as it is still impossible to observe particles separately. Azimuthal variations of temperature T observed with various α are modulated by the cooling of the particles, when they cross the Saturn's shadow. The heating rate depends on thermal inertia, whereas differences in T with a inform us on the anisotropy of emission associated with the spin rate. A thermal model of planetary ring made up of rotating icy spherical particles, distributed according to a monolayer structure, was developed to interpret observed temperatures and to understand their dependence with α and the longitude. The strong asymmetrycal emission in the C ring, observed with CAMIRAS and IRIS, suggest an average spin rate for largest particles, slightly slower than thé keplerian angular velocity Ω (ω/Ω=0. 5±0. 4). Thermal inertia of the regolith in the C ring (Γ=6±4 Jm-²K-1s-1/²) is 3 orders of magnitude weakerthan that of the crystalline water ice and indicate a porous structure, probably generated by cracks due to the permanent patching in mutual collisions, or to tensions related to the variations in T with each orbit. Similar Γ have been measured in the A ring with VISIR and CIRS instruments (Γ=6±4 Jm-²K-1s-1/²). Thermal emission of this ring is compatible with the presence of gravitational instabilities (wakes) in which the particles form aggregates.