We present spectroscopic observations of the stellar motions in the disk of
the superthin edge-on spiral galaxy IC 5249 and re-analyse synthesis obser
vations of the HI. We find that the HI rotation curve rises initially to ab
out 90-100 km s(-1), but contrary to the conclusion of Abe et al. (1999) fl
attens well before the edge of the optical disk. Over most part of the opti
cal disk we have been able to establish that the (tangential) stellar veloc
ity dispersion is 25-30 km s(-1). We argue that the central light concentra
tion in the disk is not a bulge in the classical Population II sense, but m
ost likely represents structure in the disk component. From earlier surface
photometry we adopt a value for the radial scalelength of the disk of 7 +/
- 1 kpc, a vertical scaleheight of 0.65 +/- 0.05 kpc and a disk truncation
radius of 17 +/- 1 kpc. The HI disk has a measurable thickness but from our
analysis we conclude that this is due to a small inclination away from per
fectly edge-on. The very thin appearance of IC 5249 on the sky is the resul
t of a combination of a low (face-on) surface brightness, a long scalelengt
h and a a sharp truncation at only about 2.5 scalelengths. In terms of the
ratio of the radial scalelength and the vertical scaleheight of the disk, I
C 5249 is not very at; in fact it is slightly fatter than the disk of our G
alaxy. From various arguments we derive the stellar velocity dispersions at
a position one radial scalelength out in the disk (R similar to 7 kpc) as
respectively sigma (R) similar to 35 km s(-1), sigma (theta) similar to 30
km s(-1) and sigma (z) similar to 20 km s(-1). This is comparable to the va
lues for the disk of our Galaxy in the solar neighborhood. Near the edge of
the disk the ratio of radial to vertical velocity dispersion is probably h
igher. Presumably the angular momentum distribution of the gas that formed
the disk in IC 5249 was such that, compared to the Galaxy, a much more exte
nded distribution resulted in spite of the lower overall rotation and mass.
The low surface density that arose from that resulted in a thicker HI laye
r in which star formation proceeded at a much slower rate, but disk heating
proceeded at a similar pace.