Type IIn supernova light-curve properties measured from an untargeted survey sample

Nyholm, A.; Sollerman, J.; Tartaglia, L.; Taddia, F.; Fremling, C.; Blagorodnova, N.; Filippenko, A. V.; Gal‐Yam, A.; Howell, D. A.; Karamehmetoglu, E.; Kulkarni, S. R.; Laher, Russ R.; Leloudas, G.; Masci, Frank J.; Kasliwal, Mansi M.; Morå, K.; Moriya, Takashi J.; Ofek, E. O.; Papadogiannakis, S.; Quimby, R.; Rebbapragada, Umaa; Schulze, S.

doi:10.1051/0004-6361/201936097

Cited by 73 publications

(69 citation statements)

References 154 publications

(213 reference statements)

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“…Most observed precursors develop quite slowly as pointed out in Section 6.1.1. Nyholm et al (2020) measured the rise and decline rates for ∼30 Type IIn SNe from the PTF/iPTF sample and the precursors we detect rise more slowly than any Type IIn SNe in their sample. A possible explanation could be that the precursor shock front propagates with a substantially lower velocity compared to the SN ejecta.…”

Section: Interaction-powered Precursorsmentioning

confidence: 92%

“…With rise times of 4-25 days, all SNe with detected precursors are part of the fast-rising subgroup identified by Nyholm et al (2020) 26 which includes approximately twothirds of the Type IIn SNe in their sample. A likely explanation is that fast-rising SNe IIn are typically fainter (Nyholm et al 2020) and our precursor search is most sensitive to nearby, faint SNe (see Figure 12). We here assume that energetic precursors eject more material and search for a correlation between the radiative precursor energy and the estimated SN rise time.…”

Section: Correlations With Sn Propertiesmentioning

confidence: 99%

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Bright, Months-long Stellar Outbursts Announce the Explosion of Interaction-powered Supernovae

Strotjohann

Ofek

Gal‐Yam

et al. 2021

ApJ

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Interaction-powered supernovae (SNe) explode within an optically thick circumstellar medium (CSM) that could be ejected during eruptive events. To identify and characterize such pre-explosion outbursts, we produce forcedphotometry light curves for 196 interacting SNe, mostly of Type IIn, detected by the Zwicky Transient Facility between early 2018 and 2020 June. Extensive tests demonstrate that we only expect a few false detections among the 70,000 analyzed pre-explosion images after applying quality cuts and bias corrections. We detect precursor eruptions prior to 18 Type IIn SNe and prior to the Type Ibn SN 2019uo. Precursors become brighter and more frequent in the last months before the SN and month-long outbursts brighter than magnitude −13 occur prior to 25% (5-69%, 95% confidence range) of all Type IIn SNe within the final three months before the explosion. With radiative energies of up to 10 49 erg, precursors could eject ∼1 M e of material. Nevertheless, SNe with detected precursors are not significantly more luminous than other SNe IIn, and the characteristic narrow hydrogen lines in their spectra typically originate from earlier, undetected mass-loss events. The long precursor durations require ongoing energy injection, and they could, for example, be powered by interaction or by a continuum-driven wind. Instabilities during the neon-and oxygen-burning phases are predicted to launch precursors in the final years to months before the explosion; however, the brightest precursor is 100 times more energetic than anticipated.

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Section: Interaction-powered Precursorsmentioning

confidence: 92%

Section: Correlations With Sn Propertiesmentioning

confidence: 99%

Bright, Months-long Stellar Outbursts Announce the Explosion of Interaction-powered Supernovae

Strotjohann

Ofek

Gal‐Yam

et al. 2021

ApJ

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“…SNe IIn (which for this purpose we take to include all events classified as SLSN-II on TNS, most but not all of which show SN IIn-like narrow features) obey the opposite correlation: more slowly declining events are on average more luminous, in agreement with Ofek et al (2014) and Nyholm et al (2020). This relation may turn over toward the short-timescale end of the diagram: Type Ibn SNe form a small cluster of luminous CSM-interacting hydrogen-poor transients, of which the shortest events are generally more luminous than the longer ones, but the sample is small and the trend is not significant.…”

Section: Sne and Luminosity-duration Correlationsmentioning

confidence: 99%

The Zwicky Transient Facility Bright Transient Survey. II. A Public Statistical Sample for Exploring Supernova Demographics*

Perley

Fremling

Sollerman

et al. 2020

ApJ

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179

169

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We present a public catalog of transients from the Zwicky Transient Facility (ZTF) Bright Transient Survey, a magnitude-limited (m<19 mag in either the g or r filter) survey for extragalactic transients in the ZTF public stream. We introduce cuts on survey coverage, sky visibility around peak light, and other properties unconnected to the nature of the transient, and show that the resulting statistical sample is spectroscopically 97% complete at <18 mag, 93% complete at <18.5 mag, and 75% complete at <19 mag. We summarize the fundamental properties of this population, identifying distinct duration-luminosity correlations in a variety of supernova (SN) classes and associating the majority of fast optical transients with well-established spectroscopic SN types (primarily SN Ibn and II/IIb). We measure the Type Ia SN and core-collapse (CC) SN rates and luminosity functions, which show good consistency with recent work. About 7% of CCSNe explode in very low-luminosity galaxies (M i >−16 mag), 10% in red-sequence galaxies, and 1% in massive ellipticals. We find no significant difference in the luminosity or color distributions between the host galaxies of SNe Type II and SNe Type Ib/c, suggesting that line-driven wind stripping does not play a major role in the loss of the hydrogen envelope from their progenitors. Future large-scale classification efforts with ZTF and other wide-area surveys will provide highquality measurements of the rates, properties, and environments of all known types of optical transients and limits on the existence of theoretically predicted but as yet unobserved explosions.

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“…The narrow Hα P Cygni feature is measured to have a blue velocity at zero intensity (BVZI) of 106 ± 6 km s −1 and a P Cygni minimum velocity of 66 ± 6 km s −1 . This line component is observed in many SNe IIn and is thought to be formed from outer unshocked circumstellar material (CSM) that is excited by the emission originating from the shock region (see, e.g., Kiewe et al 2012;Taddia et al 2013;Nyholm et al 2020). As a result, the BVZI value of this component provides a measure of the CSM velocity.…”

Section: Spectroscopymentioning

confidence: 99%

The Carnegie Supernova Project II

Stritzinger

Taddia

Fraser

et al. 2020

A&A

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We present optical and near-infrared broadband photometry and optical spectra of AT 2014ej from the Carnegie Supernova Project-II. These observations are complemented with data from the CHilean Automatic Supernova sEarch, the Public ESO Spectroscopic Survey of Transient Objects, and from the Backyard Observatory Supernova Search. Observational signatures of AT 2014ej reveal that it is similar to other members of the gap-transient subclass known as luminous red novae (LRNe), including the ubiquitous double-hump light curve and spectral properties similar to that of LRN SN 2017jfs. A medium-dispersion visual-wavelength spectrum of AT 2014ej taken with the Magellan Clay telescope exhibits a P Cygni Hα feature characterized by a blue velocity at zero intensity of ≈110 km s−1 and a P Cygni minimum velocity of ≈70 km s−1. We attribute this to emission from a circumstellar wind. Inspection of pre-outbust Hubble Space Telescope images yields no conclusive progenitor detection. In comparison with a sample of LRNe from the literature, AT 2014ej lies at the brighter end of the luminosity distribution. Comparison of the ultra-violet, optical, infrared light curves of well-observed LRNe to common-envelope evolution models from the literature indicates that the models underpredict the luminosity of the comparison sample at all phases and also produce inconsistent timescales of the secondary peak. Future efforts to model LRNe should expand upon the current parameter space we explore here and therefore may consider more massive systems and a wider range of dynamical timescales.

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Type IIn supernova light-curve properties measured from an untargeted survey sample

Cited by 73 publications

References 154 publications

Bright, Months-long Stellar Outbursts Announce the Explosion of Interaction-powered Supernovae

Bright, Months-long Stellar Outbursts Announce the Explosion of Interaction-powered Supernovae

The Zwicky Transient Facility Bright Transient Survey. II. A Public Statistical Sample for Exploring Supernova Demographics*

The Carnegie Supernova Project II

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