The Brownian Motion of Dust Particles in the Solar Nebula: an Experimental Approach to the Problem of Pre-planetary Dust Aggregation
J. Blum, G. Wurm, S. Kempf, T. Henning;
Icar, 1996, 124, 441
ABSTRACT:Laboratory experiments were performed to study the Brownian motion of mum-sized dust grains and small aggregates under pre-planetary nebula
conditions, i.e., in a thin gas atmosphere (Epstein drag regime), in the ballistic
limit, and under microgravity conditions.
The results of these
experiments, i.e., the grain diffusivities, are in quantitative agreement with
theoretical predictions for single spherical grains.
Deviations from particle
sphericity, i.e., in our case aggregates consisting of monodisperse spherical
grains, cause only minor deviations between the Epstein drag formula for
spheres and our experimental results for equal particle cross section.
Thus,
we find a quantitative agreement of our measurements with the Epstein
relation D ~ 1/sigma_a between grain diffusivity and geometrical
(aerodynamic) cross section.
The results of our investigations can be used for the
calculation of the gas-grain stopping time tau_f = epsilon (m/sigma_a)
(1/rho_gv_m) which, in turn, is an important grain characteristic for the
calculation of pre-planetary dust aggregation.
Here, m and sigma_a are the mass
and the aerodynamic, i.e., geometric cross section of the grain, rho_g and
v_m are the mass density of the gas and the mean thermal velocity of the gas
molecules, and epsilon is a proportionality factor which we determined to be
epsilon = 0.68 +/- 0.10.
The gas-grain stopping time describes the strength of
grain coupling to a given gas motion and its value determines relative
velocities and, hence, collision frequencies between dust grains due to
sedimentation, drag-induced orbital decay, and gas turbulence in the solar nebula.
PERSOKEY:dust, size distribution, ,
CODE: blum96