Type Ia SN 2019ein: New Insights into the Similarities and diversities among High-Velocity SNe Ia.

We present optical observations of type Ia supernova (SN) 2019ein, starting at 0.3 days since the discovery. The spectra and the light curves show that SN 2019ein belongs to the High-Velocity (HV) group with relatively rapid decline in the light curves (delta m15(B)=1.36+-0.02 mag) and the short rise time. The Si ii 6355 velocity, associated with a photospheric component but not with a detached high-velocity feature, reached 20,000 km s-1 in our first spectrum taken at 12 days before the B-band maximum. This is among the highest velocity seen in SNe Ia. The line velocity however decreased very rapidly and smoothly toward the maximum light, where it was 13,000 km s-1 as relatively low among HV SNe. The rapid spectral evolution and the short rise time are probably linked to the rapidly evolving light curves, suggesting that not only the (maximum) velocity but also the light curve decline rate are controlling functions of the observational properties of HV SNe. The earliest light curves did not show noticeable excess, ruling out a giant companion star. Spectral synthesis modeling shows that the outermost layer at >17,000 km s-1 is well described by the O-Ne-C burning layer extending to at least 25,000 km s-1, and there is no unburnt carbon below 30,000 km s-1; these properties are largely consistent with the delayed detonation scenario, and it is shared with the prototypical HV SN 2002bo despite large difference in delta m15(B). This structure is strikingly different from that derived for the well-studied NV (Normal-Velocity) SN 2011fe; we suggest that the relation between the mass of 56Ni (or delta m15) and the extent of the O-Ne-C provides an important constraint on the explosion mechanism(s) of HV and NV SNe.