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| SN 2011kf , the SIMBAD biblio (39 results) | C.D.S. - SIMBAD4 rel 1.8 - 2024.04.20CEST04:52:15 |
Sort references on where and how often the object is cited
trying to find the most relevant references on this object.
More on score
| 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 |
|---|---|---|---|---|---|---|---|---|---|
| 2013ApJ...770..128I | 1528 | K A | D | S X C | 38 | 23 | 332 | Super-luminous type IC supernovae: catching a magnetar by the tail. | INSERRA C., SMARTT S.J., JERKSTRAND A., et al. |
| 2014ApJ...787..138L | 530 | D | X C | 13 | 32 | 225 | Hydrogen-poor superluminous supernovae and long-duration gamma-ray bursts have similar host galaxies. | LUNNAN R., CHORNOCK R., BERGER E., et al. | |
| 2014ApJ...796...87I | 253 | D | S X C | 5 | 28 | 79 | Superluminous supernovae as standardizable candles and high-redshift distance probes. | INSERRA C. and SMARTT S.J. | |
| 2014MNRAS.444.2096N | 42 | X | 1 | 17 | 135 | Superluminous supernovae from PESSTO. | NICHOLL M., SMARTT S.J., JERKSTRAND A., et al. | ||
| 2015ApJ...799..107W | 120 | X | 3 | 15 | 47 | Superluminous supernovae powered by magnetars: late-time light curves and hard emission leakage. | WANG S.Q., WANG L.J., DAI Z.G., et al. | ||
| 2015AJ....149..165W | 16 | D | 1 | 11 | 15 | Testing cosmological models with Type IC super luminous supernovae. | WEI J.-J., WU X.-F. and MELIA F. | ||
| 2012ATel.3873....1D | 39 | X | 1 | 44 | 6 | 33 SN candidates from CRTS. | DRAKE A.J., DJORGOVSKI S.G., MAHABAL A.A., et al. | ||
| 2012ATel.3883....1P | 155 | T | X | 3 | 2 | 3 |
CSS111230:143658+163057 : a luminous type Ic SN at z=0.245. |
PRIETO J.L., DRAKE A.J., MAHABAL A.A., et al. | |
| 2012ATel.4498....1D | 39 | X | 1 | 28 | 4 | Classification of CRTS optical transients. | DRAKE A.J., MAHABAL A.A., DJORGOVSKI S.G., et al. | ||
| 2015MNRAS.449..917L | 18 | D | 4 | 29 | 173 | Spectroscopy of superluminous supernova host galaxies. A preference of hydrogen-poor events for extreme emission line galaxies. | LELOUDAS G., SCHULZE S., KRUHLER T., et al. | ||
| 2015MNRAS.449.1215P | 199 | X C | 4 | 25 | 41 | DES13S2cmm: the first superluminous supernova from the Dark Energy Survey. | PAPADOPOULOS A., D'ANDREA C.B., SULLIVAN M., et al. | ||
| 2015MNRAS.452.3869N | 17 | D | 2 | 55 | 156 | On the diversity of superluminous supernovae: ejected mass as the dominant factor. | NICHOLL M., SMARTT S.J., JERKSTRAND A., et al. | ||
| 2016ApJ...817..132D | 45 | X | 1 | 10 | 52 | The most luminous supernova ASASSN-15lh: signature of a newborn rapidly rotating strange quark star. | DAI Z.G., WANG S.Q., WANG J.S., et al. | ||
2016MNRAS.458...84A 
|
136 | D | X | 4 | 127 | 46 | A Hubble Space Telescope survey of the host galaxies of Superluminous Supernovae. | ANGUS C.R., LEVAN A.J., PERLEY D.A., et al. | |
| 2016MNRAS.460L..55M | 16 | D | 1 | 23 | 10 | Constraining the ellipticity of strongly magnetized neutron stars powering superluminous supernovae. | MORIYA T.J. and TAURIS T.M. | ||
| 2016MNRAS.460.3232C | 16 | D | 1 | 128 | 5 | Physical conditions and element abundances in supernova and γ-ray burst host galaxies at different redshifts. | CONTINI M. | ||
| 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. | ||
| 2016A&A...596A..67R | 161 | X C | 3 | 60 | 14 | SN 2012aa: A transient between Type Ibc core-collapse and superluminous supernovae. | ROY R., SOLLERMAN J., SILVERMAN J.M., et al. | ||
| 2017ApJ...840...12Y | 17 | D | 3 | 38 | 51 | A statistical study of superluminous supernovae using the magnetar engine model and implications for their connection with gamma-ray bursts and hypernovae. | YU Y.-W., ZHU J.-P., LI S.-Z., et al. | ||
| 2017ApJ...842...26L | 301 | D | X C | 7 | 26 | 23 | A Monte Carlo approach to magnetar-powered transients. I. Hydrogen-deficient superluminous supernovae. | LIU L.-D., WANG S.-Q., WANG L.-J., et al. | |
|
2017ApJ...845...85L
|
17 | D | 1 | 47 | 77 | Analyzing the largest spectroscopic data set of hydrogen-poor super-luminous supernovae. | LIU Y.-Q., MODJAZ M. and BIANCO F.B. | ||
| 2017MNRAS.470.3566C | 99 | D | F | 8 | 22 | 54 | Superluminous supernova progenitors have a half-solar metallicity threshold. | CHEN T.-W., SMARTT S.J., YATES R.M., et al. | |
| 2017ApJ...850...55N | 101 | D | X | 3 | 41 | 176 | The magnetar model for Type I superluminous supernovae. I. Bayesian analysis of the full multicolor light-curve sample with MOSFiT. | NICHOLL M., GUILLOCHON J. and BERGER E. | |
| 2018MNRAS.473.1258S | 17 | D | 3 | 75 | 131 | Cosmic evolution and metal aversion in superluminous supernova host galaxies. | SCHULZE S., KRUHLER T., LELOUDAS G., et al. | ||
| 2018ApJ...854...37S | 41 | X | 1 | 13 | 12 | Studying the ultraviolet spectrum of the first spectroscopically confirmed Supernova at redshift two. | SMITH M., SULLIVAN M., NICHOL R.C., et al. | ||
| 2018ApJ...854..175I | 16 | D | 1 | 48 | 19 | A statistical approach to identify superluminous supernovae and probe their diversity. | INSERRA C., PRAJS S., GUTIERREZ C.P., et al. | ||
| 2018ApJ...855....2Q | 17 | D | 2 | 63 | 93 | Spectra of hydrogen-poor superluminous supernovae from the Palomar Transient Factory. | QUIMBY R.M., DE CIA A., GAL-YAM A., et al. | ||
| 2018A&A...611A..45R | 82 | X | 2 | 47 | 13 | Search for γ-ray emission from superluminous supernovae with the Fermi-LAT. | RENAULT-TINACCI N., KOTERA K., NERONOV A., et al. | ||
| 2018ApJ...867..113M | 16 | D | 2 | 37 | 11 | Systematic investigation of the fallback accretion-powered model for hydrogen-poor superluminous supernovae. | MORIYA T.J., NICHOLL M. and GUILLOCHON J. | ||
| 2018ApJ...869..166V | 16 | D | 1 | 58 | 6 | Superluminous supernovae in LSST: rates, detection metrics, and light-curve modeling. | VILLAR V.A., NICHOLL M. and BERGER E. | ||
| 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...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 | 17 | D | 1 | 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. | ||
| 2021MNRAS.502.1678K | 261 | X C | 5 | 51 | 12 | SN 2020ank: a bright and fast-evolving H-deficient superluminous supernova. | KUMAR A., KUMAR B., PANDEY S.B., et al. | ||
| 2021ApJ...912...21E | 409 | D | S X | 9 | 125 | 18 | Late-time radio and millimeter observations of superluminous supernovae and long gamma-ray bursts: implications for central engines, fast radio bursts, and obscured star formation. | EFTEKHARI T., MARGALIT B., OMAND C.M.B., et al. | |
| 2021MNRAS.504.2535I | 17 | D | 1 | 31 | 24 | The first Hubble diagram and cosmological constraints using superluminous supernovae. | INSERRA C., SULLIVAN M., ANGUS C.R., et al. | ||
| 2021ApJ...922...17H | 235 | D | X C | 5 | 40 | 2 | A VLA survey of late-time radio emission from superluminous supernovae and the host galaxies. | HATSUKADE B., TOMINAGA N., MOROKUMA T., et al. | |
| 2024ApJ...961..169H | 20 | D | 2 | 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. |
