Where Outflows Meet Inflows: Gas Kinematics in SSA22 Lyman-{\alpha} Blob 2 Decoded by Advanced Radiative Transfer Modelling

We present new spectroscopic observations of Ly$\alpha$ Blob 2 (LAB2) in the SSA22 protocluster region ($z \sim$ 3.1). By creating a narrow-band Ly$\alpha$ image, we observed extended Ly$\alpha$ emission in three distinct regions, in which the highest Ly$\alpha$ surface brightness (SB) center is far away from the known continuum sources. We have searched through the MOSFIRE slits that cover the high Ly$\alpha$ SB regions, but are unable to detect any significant nebular emission near the highest SB center. We further map the blue-to-red flux ratio and find that it is anti-correlated with Ly$\alpha$ SB with a power-law index of $\sim$ -0.4. To decode the spatially-resolved Ly$\alpha$ profiles using Monte-Carlo radiative transfer (MCRT) modelling, we use both multiphase, clumpy models and shell models and successfully reproduced the diverse Ly$\alpha$ morphologies with reasonable physical parameters. Significant correlations exist between parameters of two different models, and our multiphase, clumpy model parameters naturally alleviated the previously reported discrepancies between the shell model parameters and data. In addition, we have modeled Ly$\alpha$ spectra at different spatial positions simultaneously, and we find that the variation of the inferred clump outflow velocity can be approximately explained by line-of-sight projection effects. Our results support the `central powering + scattering' scenario, i.e. the Ly$\alpha$ photons are generated by a central powering source and then scatter with outflowing, multiphase HI gas while propagating outwards. The infalling of cool gas near the blob outskirts shapes the observed blue-dominated Ly$\alpha$ profiles, but its energy contribution is likely to be minor compared to the photo-ionization by star-forming galaxies and/or AGNs.