The evolution of superluminous supernova LSQ14mo  and its interacting host galaxy system

Chen, Ting-Wan; Nicholl, M.; Smartt, S. J.; Mazzali, P. A.; Yates, Robert M.; Moriya, Takashi J.; Inserra, C.; Langer, N.; Kruehler, T.; Pan, Y.-C.; Kotak, R.; Galbany, L.; Schady, P.; Wiseman, P.; Greiner, J.; Schulze, S.; Man, Allison; Jerkstrand, A.; Smith, K.; Dennefeld, M.; Baltay, C.; Bolmer, J.; Kankare, E.; Knust, F.; Maguire, K.; Rabinowitz, D.; Rostami, S.; Sullivan, M.; Young, D. R.

doi:10.1051/0004-6361/201630163

Cited by 72 publications

(47 citation statements)

References 132 publications

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“…Rearrangement of gas in the galaxy, gas transfer, or the interaction causing metal-poor H i gas to be funneled into the galaxy could explain the occurrence of a SLSN Type I at low metallicity even in this solar-metallicity galaxy and indeed there is a small population of metal-poor stars present at the SLSN site. New SF activity due to interaction was also proposed for three other SLSN-I hosts (Cikota et al 2017;Chen et al 2017a).…”

Section: Discussionmentioning

confidence: 90%

The host of the Type I SLSN 2017egm

Izzo

Thöne

García-Benito

et al. 2018

A&A

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Context. Type I superluminous supernova (SLSN) host galaxies are predominantly low-metallicity, highly star-forming (SF) dwarfs. One of the current key questions is whether Type I SLSNe can only occur in such environments and hosts. Aims. Here we present an integral-field study of the massive, high-metallicity spiral NGC 3191, the host of SN 2017egm, the closest Type I SLSN known to date. We use data from PMAS/CAHA and the public MaNGA survey to shed light on the properties of the SLSN site and the origin of star formation in this non-starburst spiral galaxy. Methods. We map the physical properties of different H ii regions throughout the galaxy and characterise their stellar populations using the STARLIGHT fitting code. Kinematical information allows us to study a possible interaction with its neighbouring galaxy as the origin of recent star formation activity which could have caused the SLSN. Results. NGC 3191 shows intense star formation in the western part with three large SF regions of low metallicity. Taking only the properties of emitting gas, the central regions of the host have a higher metallicity, a lower specific star formation rate, and lower ionisation. Modelling the stellar populations gives a different picture: the SLSN region has two dominant stellar populations with different ages, the younger one with an age of 2–10 Myr and lower metallicity, likely the population from which the SN progenitor originated. Emission line kinematics of NGC 3191 show indications of interaction with its neighbour MCG+08-19-017 at ~45 kpc, which might be responsible for the recent starburst. In fact, this galaxy pair has hosted a total of four SNe, 1988B (Type Ia), SN 2003ds (Type Ic in MCG+08-19-017), PTF10bgl (Type II), and 2017egm, underlying the enhanced SF in both galaxies due to interaction. Conclusions. Our study shows that care should be taken when interpreting global host and even gas properties without looking at the stellar population history of the region. The SLSNe seem to be consistent with massive stars (>20 M⊙) requiring low metallicity (<0.6 Z⊙), environments that can also occur in massive late-type galaxies, but not necessarily with starbursts.

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Section: Discussionmentioning

confidence: 90%

The host of the Type I SLSN 2017egm

Izzo

Thöne

García-Benito

et al. 2018

A&A

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“…There are other examples of potentially merging systems hosting cosmic explosions, detected in absorption line profiles such as GRB 090323 (Savaglio et al 2012) and GRB 100219A (Thöne et al 2013), and in imaging of the hosts (GRB 051022;Castro-Tirado et al 2007;Rol et al 2007, and GRB060814;Perley et al 2013). Similarly, interacting systems have also been detected in the host systems of superluminous supernovae (Chen et al 2017;Perley et al 2016a). However, the detection of mergers in GRB and SN hosts could be coincidental, especially at high redshift where mergers are much more frequent (e.g.…”

Section: Grbs and Sne In Interacting Systemsmentioning

confidence: 99%

Gas inflow and outflow in an interacting high-redshift galaxy

Wiseman

Perley

Schady

et al. 2017

A&A

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We reveal multiple components of an interacting galaxy system at z ≈ 3.35 through a detailed analysis of the exquisite high-resolution Keck/HIRES spectrum of the afterglow of a gamma-ray burst (GRB). Through Voigt-profile fitting of absorption lines from the Lyman-series, we constrain the neutral hydrogen column density to N H i ≤ 10 18.35 cm −2 for the densest of four distinct systems at the host redshift of GRB 080810, among the lowest N H i ever observed in a GRB host, despite the line of sight passing within a projected 5 kpc of the galaxy centres. By detailed analysis of the corresponding metal absorption lines, we derive chemical, ionic and kinematic properties of the individual absorbing systems, and thus build a picture of the host as a whole. Striking differences between the systems imply that the line of sight passes through several phases of gas: the star-forming regions of the GRB host; enriched material in the form of a galactic outflow; the hot and ionised halo of a second, interacting galaxy falling towards the host at a line-of-sight velocity of 700 km s −1 ; and a cool, metal-poor cloud which may represent one of the best candidates yet for the inflow of metal-poor gas from the intergalactic medium.

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“…Thus the host and its bright neighbour appear to be a close analogue of the MW-SMC system. Chen et al (2017) found that the host of one SLSN, LSQ14mo, was in a likely interacting system with a projected separation of 15 kpc, and proposed that this could increase the likelihood of SLSNe by triggering vigorous star formation. The brightest and bluest pixels in our HST images, likely corresponding to the highest starformation rate, actually appear to be on the other side of the galaxy, though we cannot exclude comparable starformation at the position of SN 2015bn until the SLSN has completely faded.…”

Section: Galaxy Spectroscopymentioning

confidence: 99%

One Thousand Days of SN2015bn: HST Imaging Shows a Light Curve Flattening Consistent with Magnetar Predictions

Nicholl

Blanchard

Berger

et al. 2018

ApJL

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We present the first observations of a Type I superluminous supernova (SLSN) at 1000 days after maximum light. We observed SN 2015bn using the Hubble Space Telescope Advanced Camera for Surveys in the F475W, F625W and F775W filters at 721 days and 1068 days. SN 2015bn is clearly detected and resolved from its compact host, allowing reliable photometry. A galaxy template constructed from these data further enables us to isolate the SLSN flux in deep ground-based imaging. We measure a light curve decline rate at > 700 days of 0.19 ± 0.03 mag (100 d) −1 , much shallower than the earlier evolution, and slower than previous SLSNe (at any phase) or the decay rate of 56 Co. Neither additional radioactive isotopes nor a light echo can consistently account for the slow decline. A spectrum at 1083 days shows the same [O I] λ6300 and [Ca II] λ7300 lines as seen at ∼ 300 − 400 days, with no new features to indicate strong circumstellar interaction. Radio limits with the Very Large Array rule out an extended wind for mass-loss rates 10 −2.7 Ṁ /v 10 10 −1.1 M yr −1 (where v 10 is the wind velocity in units of 10 km s −1 ). The optical light curve is consistent with L ∝ t −4 , which we show is expected for magnetar spin-down with inefficient trapping; furthermore, the evolution matches predictions from earlier magnetar model fits. The opacity to magnetar radiation is constrained at ∼ 0.01 cm 2 g −1 , consistent with photon-matter pair-production over a broad ∼GeV-TeV range. This suggests the magnetar spectral energy distribution, and hence the 'missing energy' leaking from the ejecta, may peak in this range.

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The evolution of superluminous supernova LSQ14mo and its interacting host galaxy system

Cited by 72 publications

References 132 publications

The host of the Type I SLSN 2017egm

The host of the Type I SLSN 2017egm

Gas inflow and outflow in an interacting high-redshift galaxy

One Thousand Days of SN2015bn: HST Imaging Shows a Light Curve Flattening Consistent with Magnetar Predictions

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