We present early-phase panchromatic photometric and spectroscopic coverage
spanning far-ultraviolet (FUV) to the near-infrared (NIR) regime of the nearest
hydrogen-rich core-collapse supernova in the last 25 years, SN~2023ixf. We
observe early `flash' features in the optical spectra due to a confined dense
circumstellar material (CSM). We observe high-ionization absorption lines Fe
II, Mg II in the ultraviolet spectra from very early on. We also observe a
multi-peaked emission profile of H-alpha in the spectrum beginning ~16 d, which
indicates ongoing interaction of the SN ejecta with a pre-existing shell-shaped
CSM having an inner radius of ~ 75 AU and an outer radius of ~140 AU. The
shell-shaped CSM is likely a result of enhanced mass loss ~ 35 - 65 years
before the explosion assuming a standard Red-Supergiant wind. Spectral modeling
of the FUV, NUV, and the optical spectra during 9-12 d, using the radiative
transfer spectrum synthesis code TARDIS indicates that the supernova ejecta
could be well represented by a progenitor elemental composition greater than
solar abundances. Based on early light curve models of Type II SNe, we infer
that the nearby dense CSM confined to ~7+-3e14~cm(~45 AU) is a result of
enhanced mass loss ~1e-(3.0+-0.5) Msol/yr two decades before the explosion.Comment: Submitted to AAS Journals, 4 figures, 2 table