Narrow-band images of Comet Austin 1990 V in the light of the red (0-8
-O) H2O+ emission (6199 angstrom) are presented. The observations were
carried out in the period April 30-May 7, 1990, with a focal reducer,
Fabry-Perot interferometer, and a CCD camera attached to the 1-m tele
scope of Hoher List Observatory. The high spectral resolution of the i
mages allowed a precise subtraction of the dust continuum even at the
nucleus and a reliable absolute calibration. Thus, for the first time,
the spatial distribution of water ions and its temporal behavior is o
bserved in the cometary coma including the area close to the nucleus.
Peak column densities between 10(11) and 2 x 10(11) cm-2 were obtained
in the observational period. Close to the nucleus the column density
distribution is strongly asymmetric. Toward the Sun the column density
gradient is steep. In this direction the column density decreases by
a factor of 4 over a distance of 10(4)km. In the tailward direction th
e distribution is flat. Frequently the column density maximum is shift
ed tailward. The contour passing through the nucleus usually extends m
ore than 10(4) km tailward. This is caused by the mass ioading of new
ions into the tailward cometary plasma flow. We have integrated the co
lumn densities perpendicular to the tail direction and calculated the
number of water ions per unit tail length. The derived profiles always
have their maximum significantly shifted tailward. They are compared
with a simple model of H2O+ production by photoionization of water. Go
od qualitative agreement is obtained but the mean ion velocities deduc
ed from the model are too high by about a factor of 10. Probably a sig
nificant part of the ions in the flanks of the tail is not detected in
our observations. The time interval of 22-23 min between successive i
mages allows to study turns of the plasma tail and the formation of ra
y structures near the cometary nucleus. Even strong changes in morphol
ogy have only a minor influence on the ion content per unit tail lengt
h. This indicates that tail rays are usually not caused by a modulatio
n of the ion production but that the tail ray phenomenon represents a
redirection (rechanneling) of the ion flux out of the coma from old ra
ys (main tail) into new rays. We compare our observations with MHD mod
el calculations of magnetic field tangential discontinuities passing t
hrough the cometary coma. (C) 1994 Academic Press, Inc.