Abstract
We describe high spectral resolution, high dynamic range integral field spectroscopy of IC 418 covering the spectral range 3300-8950 angstrom and compare with earlier data. We determine line fluxes, derive chemical abundances, provide a spectrum of the central star and determine the shape of the nebular continuum. Using photoionization models, we derive the reddening function from the nebular continuum and recombination lines. The nebula has a very high inner ionization parameter. Consequently, radiation pressure dominates the gas pressure and dust absorbs a large fraction of ionizing photons. Radiation pressure induces increasing density with radius. From a photoionization analysis we derive central star parameters; log T-eff = 4.525 K, log L*/L-circle dot = 4.029, log g = 3.5 and using stellar evolutionary models we estimate an initial mass of 2.5 < M/M-circle dot < 3.0. The inner filamentary shell is shocked by the rapidly increasing stellar wind ram pressure, and we model this as an externally photoionized shock. In addition, a shock is driven into the pre-existing asymptotic giant branch (AGB) stellar wind by the strong D-Type ionization front developed at the outer boundary of the nebula. From the dynamics of the inner mass-loss bubble and from stellar evolutionary models, we infer that the nebula became ionized in the last 100-200 yr, but evolved structurally during the similar to 2000 yr since the central star evolved off the AGB. The estimated current mass-loss rate ((M)over dot = 3.8 x 10(-8)M(circle dot) yr(-1)) and terminal velocity (v(infinity) similar to 450 km s(-1)) are sufficient to excite the inner mass-loss bubble. While on the AGB, the central star lost mass at. M = 2.1 x 10(-5)M(circle dot) yr(-1) with outflow velocity similar to 14 km s(-1).