Cool Stars 14 - Submitted Abstract # 318 This version created on 05 October 2006 Spectral Diagnostics of Hot Plasma from Cool Stars Nancy Brickhouse, Harvard-Smithsonian Center for Astrophysics EUV and X-ray spectra tell us about the physical conditions in the hot coronae, in particular temperature, density, elemental abundances, opacity, and velocity. The values derived from spectroscopy inform our models of magnetic structure, accretion shocks, and hot winds. But two issues must always be kept in mind: (1) the methods used are often indirect and inferential, and make a lot of assumptions; and (2) the fundamental atomic data have flaws which are often not taken into account. The proposed splinter session will address both of these issues for topics of recent interest. This session also emphasizes the solar/stellar connection. A summary of this session will be provided to the CS14 Proceedings by N. Brickhouse. The session will address three critical problems. Each problem will be discussed by a panel of 3 scientists. The panelists will briefly describe how spectroscopic measurements are used to determine a physical property or to infer some physical process. Particular emphasis will be given to the underlying systematic uncertainties. Following their presentations, the audience will be asked for comments. I. Coronal structure (temperature, density, opacity) The recent literature has pointed out problems with the ``classic'' He-like G-ratio, differences among densities derived using different diagnostics (are stellar coronae really as dense as solar flares?), and temperature discrepancies among Fe lines from the same ionization state. A concerted effort in laboratory astrophysics and atomic theory to address problems in fundamental X-ray spectroscopy was highlighted at NASA's Laboratory Astrophysics Workshop in Las Vegas this spring. Atomic theory is converging on experiment for some important diagnostic line ratios. What is the status of these calculations? What is the impact on coronal research? What does the sun tell us about individual loop structures? Can these be extrapolated to stars? For the case where we think the atomic data are ok, how well do our methods work? II. Elemental abundances in solar and stellar coronae For reasons still not well understood, coronal abundances do not in general reflect the underlying photospheric abundances. How reliable are the measurements of abundances? How much do absolute or relative abundances depend on the emission measure distribution modeling? III. Velocity measurements for high temperature plasma Chandra HETG can measure Doppler shifts to an accuracy of <25 km/s. The SOHO spectrometers routinely measure velocities of a few to 10's of km/s. Radial velocity studies are useful to constrain the location[s] of the emitting regions in stars. In conjunction with eclipse mapping or flare occultation, even more information can be obtained. Doppler shift measurements indicate the detailed dynamics of solar structures. Line widths are also potentially useful diagnostics for non-thermal broadening. What can we learn about coronae from velocity studies? ----------------------------------