Bibcode
DOI
Franco, J.; Tenorio-Tagle, G.; Rodriguez-Gaspar, J. A.
Referencia bibliográfica
Astrophysical Journal v.451, p.210
Fecha de publicación:
9
1995
Número de citas
21
Número de citas referidas
13
Descripción
We solve the line transfer problem in evolving H ii regions in order to
calculate line profiles of hydrogen recombination (Hα) and
forbidden oxygen ([O III] 5007) lines along several lines of sight
during the photo- disruption of molecular cloud cores, or high-density
condensation. The density, velocity, and ionization structure of
spherically symmetric models with an initial power-law density
distribution, ρ ∝ r-w, were used to calculate the
source function. We differentiate between two possible evolutions: the
classical evolution (w ≤ 1.5), in which upon expansion of the ionized
gas a shock is driven into the neutral intercloud medium, and evolution
for steeper density gradients (w > 1.5), in which the "champagne"
phase develops as the whole cloud becomes ionized by a supersonic R-type
ionization front. Thus a strong shock is driven into the ionized gas by
the expansion of the denser cloud core. The rapid expansion of these
high-density cores generates supersonic outflows as well as important
variations in the H II equilibrium temperature, which ranges from
103 K within the core to 8 × 104 K behind
the champagne shocks. As a result, the line profiles in these cases may
present partial or total splitting both in Hα and in [O III]
λ5007. Also the surface brightness distributions of the oxygen
line traces mainly the hot (T > 3 × 104 K) and
fast-moving shocked gas, and the Hα traces the slower, purely
photoionized matter (T 10 K). Thus the continuous and rapid disruption
of condensations, driven by the pressure imbalance created by
photoionization within a star-forming cloud, adds a supersonic bulk
motion to the uniform velocity field expected from the classical
evolution.