"The Signature of Primordial Grain Growth in the Polarized Light of
the AU Mic Debris Disk"
We have used the Hubble Space Telescope/ACS coronagraph to make
polarization maps of the AU Mic debris disk. The fractional linear
polarization rises monotonically from about 0.05 to 0.4 between 20
and 80 AU. The polarization is perpendicular to the disk, indicating
that the scattered light originates from micron sized grains in an
optically thin disk. Disk models, which simultaneously fit the
surface brightness and polarization, show that the inner disk (<
40-50 AU) is depleted of micron-sized dust by a factor of more than
300, which means that the disk is collision dominated. The grains
have high maximum linear polarization and strong forward scattering.
Spherical grains composed of conventional materials cannot reproduce
these optical properties. A Mie/Maxwell-Garnett analysis implicates
highly porous (91-94%) particles. In the inner Solar System, porous
particles form in cometary dust, where the sublimation of ices leaves
a "bird's nest" of refractory organic and silicate material. In AU
Mic, the grain porosity may be primordial, because the dust "birth
ring" lies beyond the ice sublimation point. The observed porosities
span the range of values implied by laboratory studies of particle
coagulation by ballistic cluster-cluster aggregation. To avoid
compactification, the upper size limit for the parent bodies is in
the decimeter range, in agreement with theoretical predictions based
on collisional lifetime arguments. Consequently, AU Mic may exhibit
the signature of the primordial agglomeration process whereby
interstellar grains first assembled to form macroscopic objects.
For further details please see Graham, Kalas & Matthews.