We present modeling to explore the conditions of the broad-line emitting gas in two extreme Narrow-line Seyfert 1 galaxies, using the observational results described in the first paper of this series. Photoionization modeling using Cloudy was conducted for the broad, blueshifted wind lines and the narrow, symmetric, rest-wavelength-centered disk lines separately. A broad range of physical conditions were explored for the wind component, and a figure of merit was used to quantitatively evaluate the simulation results. Of the three minima in the figure-of-merit parameter space, we favor the solution characterized by an X-ray weak continuum, elevated abundances, a small column density (log(N H ) ≈ 21.4), relatively high ionization parameter (log(U ) ≈ −1.2-−0.2), a wide range of densities (log(n) ≈ 7-11), and a covering fraction of ∼ 0.15. The presence of low-ionization emission lines implies the disk component is optically thick to the continuum, and the Si III]/C III] ratio implies a density of 10 10 -10 10.25 cm −3 . A low ionization parameter (log(U ) = −3) is inferred for the intermediate-ionization lines, unless the continuum is "filtered" through the wind before illuminating the intermediateline emitting gas, in which case log(U ) = −2.1. The location of the emission regions was inferred from the photoionization modeling and a simple "toy" dynamical model. A large black hole mass (1.3 × 10 8 M ⊙ ) radiating at 11% of the Eddington luminosity is consistent with the kinematics of both the disk and wind lines, and an emission radius of ∼ 10 4 R S is inferred for both. We compare these results with previous work and discuss implications. 3 We do not know with certainty the geometrical and physical origin of the emission lines in the objects we are -3 -The strongly blueshifted C IV profile suggested that it is dominated by emission in the wind. Following Baldwin et al. (1996), we used the C IV profile to develop a template for the wind. We then used this template, plus a narrow and symmetric component representing the disk emission, to model the other bright emission lines. We inferred that the high-ionization lines N V and He II are also dominated by wind emission, and a part of Lyα is emitted in the wind. A part of Lyα and the intermediate-and low-ionization lines Al III, Si III], C III], and Mg II are dominated by disk emission. The 1400Å feature, comprised of O IV] and Si IV was difficult to model; however, it appears to include both disk and wind emission. discussing here. However, for simplicity, we refer to the highly blueshifted high-ionization lines as originating in the "wind", and the narrow, symmetric low-ionization lines as originating in the "disk".
