分类: 天文学 >> 天文学 提交时间: 2023-02-19
摘要: We present the first analysis of photometric observations of the supernova (SN) impostor AT 2016blu located in the galaxy NGC 4559. This transient source was discovered by the Lick Observatory Supernova Search in January 2012 and has continued its eruptive variability since then. Photometry of AT 2016blu reveals at least 19 outbursts in 2012-2022. AT 2016blu's outbursts show irregular variability with multiple closely spaced peaks of varying brightness. While the individual outbursts have irregular light curves, concentrations of these peaks seem to repeat with a period of roughly 110-115 d. Based on this period, the next outburst of AT 2016blu should occur around February 2023. AT 2016blu shares some similarities with SN 2000ch in NGC 3432, where it has been proposed that brightening episodes are caused by violent encounters at periastron in a binary system containing a luminous blue variable (LBV). We propose that AT 2016blu outbursts are also driven by binary interactions that intensify around times of periastron in an eccentric system. The intrinsic variability of the LBV-like primary star may cause different intensity and duration of binary interaction at each periastron passage. The binary interaction of AT 2016blu also resembles the periastron encounters of $\eta$ Carinae leading up to its Great Eruption and the erratic pre-SN eruptions of SN 2009ip. This similarity suggests that AT 2016blu might also be headed for a catastrophe, making it a target of great interest.
分类: 天文学 >> 天文学 提交时间: 2023-02-19
摘要: A rare class of supernovae (SNe) is characterized by strong interaction between the ejecta and several solar masses of circumstellar matter (CSM) as evidenced by strong Balmer-line emission. Within the first few weeks after the explosion, they may display spectral features similar to overluminous Type Ia SNe, while at later phase their observation properties exhibit remarkable similarities with some extreme case of Type IIn SNe that show strong Balmer lines years after the explosion. We present polarimetric observations of SN2018evt obtained by the ESO Very Large Telescope from 172 to 219 days after the estimated time of peak luminosity to study the geometry of the CSM. The nonzero continuum polarization decreases over time, suggesting that the mass loss of the progenitor star is aspherical. The prominent H$\alpha$ emission can be decomposed into a broad, time-evolving component and an intermediate-width, static component. The former shows polarized signals, and it is likely to arise from a cold dense shell (CDS) within the region between the forward and reverse shocks. The latter is significantly unpolarized, and it is likely to arise from shocked, fragmented gas clouds in the H-rich CSM. We infer that SN2018evt exploded inside a massive and aspherical circumstellar cloud. The symmetry axes of the CSM and the SN appear to be similar. SN\,2018evt shows observational properties common to events that display strong interaction between the ejecta and CSM, implying that they share similar circumstellar configurations. Our preliminary estimate also suggests that the circumstellar environment of SN2018evt has been significantly enriched at a rate of $\sim0.1$ M$_\odot$ yr$^{-1}$ over a period of $>100$ yr.
分类: 天文学 >> 天文学 提交时间: 2023-02-19
摘要: Type Ia Supernovae are thermonuclear explosions of white dwarf stars. They play a central role in the chemical evolution of the Universe and are an important measure of cosmological distances. However, outstanding questions remain about their origins. Despite extensive efforts to obtain natal information from their earliest signals, observations have thus far failed to identify how the majority of them explode. Here, we present infant-phase detections of SN 2018aoz from a brightness of -10.5 absolute AB magnitudes -- the lowest luminosity early Type Ia signals ever detected -- revealing a hitherto unseen plateau in the $B$-band that results in a rapid redward color evolution between 1.0 and 12.4 hours after the estimated epoch of first light. The missing $B$-band flux is best-explained by line-blanket absorption from Fe-peak elements in the outer 1% of the ejected mass. The observed $B-V$ color evolution of the SN also matches the prediction from an over-density of Fe-peak elements in the same outer 1% of the ejected mass, whereas bluer colors are expected from a purely monotonic distribution of Fe-peak elements. The presence of excess nucleosynthetic material in the extreme outer layers of the ejecta points to enhanced surface nuclear burning or extended sub-sonic mixing processes in some normal Type Ia Supernova explosions.