Photometric, polarimetric, and spectroscopic studies of the luminous, slow-decaying Type Ib SN 2012au

Optical, near-infrared (NIR) photometric and spectroscopic studies along with the optical imaging polarimetric results for SN 2012au to constrain the nature of the progenitor and other properties are presented in this paper. Well-calibrated multi-band optical photometric data (from $-$0.2 to +413 d since $B$-band maximum) was used to compute the bolometric light curve and to perform semi$-$analytical light-curve modelling using the $\texttt{MINIM}$ code. A spin-down millisecond magnetar-powered model reasonably explains the observed photometric evolution of SN 2012au. Early time imaging polarimetric follow-up observations ($-$2 to +31 d) and their comparison with other similar cases indicate signatures of asphericity in the ejecta. Good spectral coverage of SN 2012au (from $-$5 to +391 d) allows us to trace the evolution of layers of SN ejecta in detail. SN 2012au exhibits higher line velocities in comparison to the other SNe~Ib. Late nebular phase spectra of SN 2012au indicate for a Wolf-Rayet star as the possible progenitor for SN 2012au, with oxygen, He-core, and main sequence masses of $\sim$1.62 $\pm$ 0.15 M$_\odot$, $\sim$4$-$8 M$_\odot$, and $\sim$17$-$25 M$_\odot$, respectively. There is a clear absence of first-overtone of the carbon monoxide (CO) features up to +319 d in the $K$-band region of the NIR spectra. Overall analysis suggests that SN 2012au is one of the most luminous slow-decaying Type Ib SN having comparatively higher ejecta mass ($\sim$4.7$-$8.3 M$_\odot$) and kinetic energy ($\sim$[4.8 $-$ 5.4] $\times$ 10$^{51}$ erg). Detailed modelling using the $\texttt{MESA}$ and the results obtained through $\texttt{STELLA}$ and $\texttt{SNEC}$ explosions also strongly support spin-down of a magnetar as a possible powering source of SN 2012au having mass around 20 M$_\odot$ and metallicity of Z = 0.04.