-108 K)
gas within the outflow, current models suggest an origin in
wind-shocked clouds. J.N. Bregman has kindly provided us with a
recently published ([Bregman, Schulman, & Tomisaka 1995]) image of M82 taken with the
Röntgensatellit (ROSAT; [Trümper 1984]) High-Resolution Imager
(HRI; [Pfeffermann et al. 1987]). The pair of 13' square images with
total exposure time 33.8 kiloseconds were taken in early 1991 and late
1992. The resolution is about 5''.
Contours representing the ROSAT soft x-ray flux have been
overlayed on our deep H
image (Fig. 8). The
morphologies are markedly similar, with specific filaments and knots
clearly enhanced in both emission bands. (Note, for example, the two
extensive filaments in the north, and the knots approximately 500 pc
SW of the nucleus.) But in light of the more extensive distribution
of the X-rays versus the optical emission, it seems unlikely that
all of the X-ray flux is associated with specific filaments of
optical emission. Since the regions of high optical/X-ray correlation
are also some of the brightest in H, these knots presumably
represent density enhancements in the outflow bubbles. The large
extent of the X-ray halo and close spatial correlation with the H emission suggest an interpretation in terms of shocks driven by a
fast, rarefied wind plowing into denser halo gas (e.g. [Sutherland, Bicknell, & Dopita 1993];
[Dopita & Sutherland 1996]). Our observed H/X-ray luminosity ratio of 
30
in the brightest filaments, identical to that derived by [Pérez-Olea & Colina 1996],
suggests a similar scenario. We defer detailed modeling of the H and soft x-ray emission to a subsequent paper, in which the shocks
will be constrained by deep spectroscopy and imaging from the
Keck and Hubble Space Telescopes.