Stark broadening in hot, dense laser-produced plasmas

Broadened Lyman-$alpha$ x-ray lines from neon X and argon XVIII radiators, which are immersed in a hot, dense deuterium or deuterium-tritium plasma, are discussed. In particular, these lines are analyzed for several temperature-density cases, characteristic of laser-produced plasmas; special attention paid to the relative importance of ion, electron, and Doppler effects. Static ion microfield distribution functions are tabulated

The effect of UV stars on the intergalactic medium

We have investigated the effect of ionizing radiation from the UV stars (hot prewhite dwarfs) on the intergalactic medium (IGM). If the UV stars are powered only by gravitational contraction they radiate most of their energy at a typical surface temperature of 1.5×10 5 K which produces a very highly ionized IGM in which the elements carbon, nitrogen and oxygen are left with only one or two electrons. This results in these elements being very inefficient coolants. The gas is cooled principally by free-free emission and the collisional ionization of hydrogen and helium. For a typical UV star temperature of T =1.5×10 5 K, the temperature of the ionized gas in the IGM is T g =1.2×10 5 K for a Hubble constant H o =75 km s −1 Mpc −1 and a hydrogen density n H =10 −6 cm −3 . Heating by cosmic rays and X-rays is insignificant in the IGM except perhaps in Hi clouds because when a hydrogen atom recombines in the IGM it is far more likely to be re-ionized by a UV-star photon than by of the other two types of particles due to the greater space density of UV-star photons and their appreciably larger ionization cross-sections. If the UV stars radiate a substantial fraction of their energy in a helium-burning stage in which they have surface temperatures of about 5×10 4 K, the temperature of the IGM could be lowered to about 5×10 4 K.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/42092/1/10509_2004_Article_BF00642148.pd