In a first step, the observations are interpreted using the rotational diagram method commonly used for interstellar molecular line studies. The methanol rotational distribution is best described by temperatures in the range 20 to 40 K. The corresponding column densities and methanol production rates are derived. In a second step, an out-of-equilibrium model is used where the methanol rotational distribution is governed by collisions, spontaneous relaxation, and excitation of the fundamental vibrational bands by solar radiation. This model shows that the observed distribution is sensitive to the coma kinetic temperature, and suggests that the collisional region is underestimated when taking into account only collisions with water: collisions with electrons may play a major role in the excitation of methanol.
The retrieved methanol production rates are 2.0 and 2.2 10
s
, corresponding to relative abundances of 5 and
with
respect to water, for comets Austin and Levy, respectively. These
abundances are in agreement with independent infrared observations of
cometary methanol in the same comets. They show that methanol is
indeed an important cometary volatile, and that its abundance may vary
from comet to comet. Since methanol is also found to be an abundant
constituent of interstellar grains, its presence in comets is
consistent with the scenario of formation of comets from unaltered
interstellar matter.
The photolytic decay products of methanol, such as CH
O, should be
important in cometary atmospheres, but they cannot account for the
suspected distributed sources of CO or H
CO.
(accepted for
publication in Astronomy and Astrophysics, Main Journal)