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PTF 10nmn , the SIMBAD biblio (32 results) | C.D.S. - SIMBAD4 rel 1.8 - 2024.03.28CET15:12:17 |
Bibcode/DOI | Score |
in Title|Abstract| Keywords |
in a table | in teXt, Caption, ... | Nb occurence | Nb objects in ref |
Citations (from ADS) |
Title | First 3 Authors |
---|---|---|---|---|---|---|---|---|---|
2012ApJ...748...42C | 52 | X | 1 | 5 | 139 | Effects of rotation on the minimum mass of primordial progenitors of pair-instability supernovae. | CHATZOPOULOS E. and WHEELER J.C. | ||
2012MNRAS.422.2701P | 83 | X | 2 | 4 | 52 | Pair-instability supernovae at the epoch of reionization. | PAN T., KASEN D. and LOEB A. | ||
2012MNRAS.423.2203P | 181 | A | X | 5 | 4 | 29 | Pair-instability supernovae via collision runaway in young dense star clusters. | PAN T., LOEB A. and KASEN D. | |
2012Sci...337..927G | 7 | 31 | 493 | Luminous supernovae. | GAL-YAM A. | ||||
2013MNRAS.433.1114Y | 51 | X | 1 | 7 | 170 | Evolution and fate of very massive stars. | YUSOF N., HIRSCHI R., MEYNET G., et al. | ||
2014MNRAS.437..656M | 40 | X | 1 | 19 | 62 | The superluminous supernova PS1-11ap: bridging the gap between low and high redshift. | McCRUM M., SMARTT S.J., KOTAK R., et al. | ||
2014MNRAS.438.3119Y | 40 | X | 1 | 7 | 18 | Type Ic core-collapse supernova explosions evolved from very massive stars. | YOSHIDA T., OKITA S. and UMEDA H. | ||
2014ApJ...785...37B | 39 | X | 1 | 16 | 29 | SN 2010mb: direct evidence for a supernova interacting with a large amount of hydrogen-free circumstellar material. | BEN-AMI S., GAL-YAM A., MAZZALI P.A., et al. | ||
2014A&A...565A..70K | 276 | X C | 6 | 14 | 50 | Observational properties of low-redshift pair instability supernovae. | KOZYREVA A., BLINNIKOV S., LANGER N., et al. | ||
2015ApJ...799...18C | 41 | X | 1 | 7 | 22 | Emission from pair-instability supernovae with rotation. | CHATZOPOULOS E., VAN ROSSUM D.R., CRAIG W.J., et al. | ||
2015MNRAS.449.1215P | 40 | X | 1 | 25 | 41 | DES13S2cmm: the first superluminous supernova from the Dark Energy Survey. | PAPADOPOULOS A., D'ANDREA C.B., SULLIVAN M., et al. | ||
2015MNRAS.452.1567C | 41 | X | 1 | 23 | 78 | The host galaxy and late-time evolution of the superluminous supernova PTF12dam. | CHEN T.-W., SMARTT S.J., JERKSTRAND A., et al. | ||
2015MNRAS.454.4357K | 41 | X | 1 | 5 | 19 | Can pair-instability supernova models match the observations of superluminous supernovae? | KOZYREVA A. and BLINNIKOV S. | ||
2016A&A...593A.115J | 16 | D | 1 | 31 | 11 | Taking stock of superluminous supernovae and long gamma-ray burst host galaxy comparison using a complete sample of LGRBs. | JAPELJ J., VERGANI S.D., SALVATERRA R., et al. | ||
2016ApJ...830...13P | 341 | D | S X | 8 | 42 | 174 | Host-galaxy properties of 32 low-redshift superluminous supernovae from the Palomar transient factory. | PERLEY D.A., QUIMBY R.M., YAN L., et al. | |
2018ApJ...855....2Q | 635 | D | X C | 15 | 63 | 93 | Spectra of hydrogen-poor superluminous supernovae from the Palomar Transient Factory. | QUIMBY R.M., DE CIA A., GAL-YAM A., et al. | |
2018ApJ...860..100D | 348 | D | X C | 8 | 41 | 119 | Light curves of hydrogen-poor superluminous supernovae from the Palomar Transient Factory. | DE CIA A., GAL-YAM A., RUBIN A., et al. | |
2018ApJ...866L..24N | 42 | X | 1 | 11 | 12 | One thousand days of SN2015bn: HST imaging shows a light curve flattening consistent with magnetar predictions. | NICHOLL M., BLANCHARD P.K., BERGER E., et al. | ||
2018ApJ...869..166V | 16 | D | 2 | 58 | 6 | Superluminous supernovae in LSST: rates, detection metrics, and light-curve modeling. | VILLAR V.A., NICHOLL M. and BERGER E. | ||
2019ApJ...871..102N | 144 | D | S X | 3 | 20 | 55 | Nebular-phase spectra of superluminous supernovae: physical insights from observational and statistical properties. | NICHOLL M., BERGER E., BLANCHARD P.K., et al. | |
2020ApJ...897..114B | 17 | D | 1 | 67 | ~ | The pre-explosion mass distribution of hydrogen-poor superluminous supernova progenitors and new evidence for a mass-spin correlation. | BLANCHARD P.K., BERGER E., NICHOLL M., et al. | ||
2020ApJ...902L...8Y | 44 | X | 1 | 13 | 17 | Helium-rich superluminous supernovae from the Zwicky Transient Facility. | YAN L., PERLEY D.A., SCHULZE S., et al. | ||
2020ApJ...904...74G | 17 | D | 1 | 145 | ~ | FLEET: a redshift-agnostic machine learning pipeline to rapidly identify hydrogen-poor superluminous supernovae. | GOMEZ S., BERGER E., BLANCHARD P.K., et al. | ||
2020A&A...643A..47O | 17 | D | 1 | 93 | ~ | The interacting nature of dwarf galaxies hosting superluminous supernovae. | ORUM S.V., IVENS D.L., STRANDBERG P., et al. | ||
2021ApJ...909...24K | 192 | D | X | 5 | 93 | ~ | Photospheric velocity gradients and ejecta masses of hydrogen-poor superluminous supernovae: proxies for distinguishing between fast and slow events. | KONYVES-TOTH R. and VINKO J. | |
2021ApJS..255...29S | 17 | D | 1 | 893 | 63 | The Palomar Transient Factory core-collapse supernova host-galaxy sample. I. Host-galaxy distribution functions and environment dependence of core-collapse supernovae. | SCHULZE S., YARON O., SOLLERMAN J., et al. | ||
2022ApJ...940...69K | 108 | D | X | 3 | 32 | 2 | Premaximum Spectroscopic Diversity of Hydrogen-poor Superluminous Supernovae. | KONYVES-TOTH R. | |
2022ApJ...941..107G | 45 | X | 1 | 238 | 16 | Luminous Supernovae: Unveiling a Population between Superluminous and Normal Core-collapse Supernovae. | GOMEZ S., BERGER E., NICHOLL M., et al. | ||
2023ApJ...943...41C | 19 | D | 2 | 71 | 17 | The Hydrogen-poor Superluminous Supernovae from the Zwicky Transient Facility Phase I Survey. I. Light Curves and Measurements. | CHEN Z.H., YAN L., KANGAS T., et al. | ||
2023ApJ...954...44K | 159 | D | X | 4 | 29 | ~ | Type W and Type 15bn Subgroups of Hydrogen-poor Superluminous Supernovae: Premaximum Diversity, Postmaximum Homogeneity? | KONYVES-TOTH R. and SELI B. | |
2024ApJ...961..146U | 50 | X | 1 | 8 | ~ | Metal-enriched Pair-instability Supernovae: Effects of Rotation. | UMEDA H. and NAGELE C. | ||
2024ApJ...961..169H | 20 | D | 1 | 110 | ~ | An Extensive Hubble Space Telescope Study of the Offset and Host Light Distributions of Type I Superluminous Supernovae. | HSU B., BLANCHARD P.K., BERGER E., et al. |