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iPTF 13ehe , the SIMBAD biblio (71 results) | C.D.S. - SIMBAD4 rel 1.8 - 2024.06.17CEST08:49:02 |
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 |
---|---|---|---|---|---|---|---|---|---|
2015ApJ...814..108Y | 2887 | K A | S X C | 71 | 9 | 72 | Detection of broad Hα emission lines in the late-time spectra of a hydrogen-poor superluminous supernova. | YAN L., QUIMBY R., OFEK E., et al. | |
2015A&A...584L...5M | 1616 | K A | S X | 40 | 2 | 17 | Revealing the binary origin of Type Ic superluminous supernovae through nebular hydrogen emission. | MORIYA T.J., LIU Z.-W., MacKEY J., et al. | |
2016ApJ...817..132D | 125 | X C | 2 | 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. | ||
2016ApJ...818...77O | 763 | K A | D | S X C | 18 | 10 | 7 | Quark-novae occurring in massive binaries : a universal energy source in superluminous supernovae with double-peaked light curves. | OUYED R., LEAHY D. and KONING N. |
2016ApJ...820...75P | 120 | X | 3 | 47 | 24 | Line identifications of Type I supernovae: on the detection of Si II for these hydrogen-poor events. | PARRENT J.T., MILISAVLJEVIC D., SODERBERG A.M., et al. | ||
2016MNRAS.457..351Y | 42 | X | 1 | 7 | 14 | Mass ejection by pulsational pair instability in very massive stars and implications for luminous supernovae. | YOSHIDA T., UMEDA H., MAEDA K., et al. | ||
2016ApJ...826...39N | 87 | X | 2 | 18 | 133 | SN 2015BN: a detailed multi-wavelength view of a nearby superluminous supernova. | NICHOLL M., BERGER E., SMARTT S.J., et al. | ||
2016ApJ...826..178G | 86 | X | 2 | 6 | 37 | Explaining the most energetic supernovae with an inefficient jet-feedback mechanism. | GILKIS A., SOKER N. and PAPISH O. | ||
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. | ||
2015ATel.8086....1B | 41 | X | 1 | 2 | 6 | Ultraviolet Rebrightening of Superluminous Supernova ASASSN-15lh. | BROWN P.J. | ||
2016ApJ...828....3B | 81 | X | 2 | 15 | 22 | ASASSN-15lh: a superluminous ultraviolet rebrightening observed by Swift and Hubble. | BROWN P.J., YANG Y., COOKE J., et al. | ||
2016ApJ...828...87W | 1375 | T K A | D | S X C | 32 | 3 | 30 |
A triple-energy-source model for superluminous supernova iPTF13ehe. |
WANG S.Q., LIU L.D., DAI Z.G., et al. |
2016ApJ...829...17S | 48 | X | 1 | 7 | 60 | Type I superluminous supernovae as explosions inside non-hydrogen circumstellar envelopes. | SOROKINA E., BLINNIKOV S., NOMOTO K., et al. | ||
2015ATel.8216....1M | 41 | X | 1 | 2 | 6 | Optical spectroscopy of ASASSN-15lh reveal no clear signs of interaction with an H-rich circumstellar environment. | MILISAVLJEVIC D., JAMES D.J., MARSHALL J.L., et al. | ||
2016ApJ...831..144L | 404 | X C | 9 | 14 | 54 | PS1-14bj: a hydrogen-poor superluminous supernova with a long rise and slow decay. | LUNNAN R., CHORNOCK R., BERGER E., et al. | ||
2017ApJ...835...13J | 45 | X | 1 | 22 | 99 | Long-duration superluminous supernovae at late times. | JERKSTRAND A., SMARTT S.J., INSERRA C., et al. | ||
2017ApJ...835...58V | 43 | X | 1 | 14 | 40 | On the early-time excess emission in hydrogen-poor superluminous supernovae. | VREESWIJK P.M., LELOUDAS G., GAL-YAM A., et al. | ||
2017ApJ...835..140M | 41 | X | 1 | 194 | 134 | Ejection of the massive hydrogen-rich envelope timed with the collapse of the stripped SN 2014C. | MARGUTTI R., KAMBLE A., MILISAVLJEVIC D., et al. | ||
2017ApJ...836...25M | 48 | X | 1 | 9 | 63 | X-rays from the location of the double-humped transient ASASSN-15lh. | MARGUTTI R., METZGER B.D., CHORNOCK R., et al. | ||
2017MNRAS.466.1428G | 247 | X | 6 | 11 | 38 | The unexpected, long-lasting, UV rebrightening of the superluminous supernova ASASSN-15lh. | GODOY-RIVERA D., STANEK K.Z., KOCHANEK C.S., et al. | ||
2017ApJ...840...12Y | 139 | D | X | 4 | 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. | |
2017A&A...602A...9C | 42 | X | 1 | 25 | 37 | The evolution of superluminous supernova LSQ14mo and its interacting host galaxy system. | CHEN T.-W., NICHOLL M., SMARTT S.J., et al. | ||
2017MNRAS.468.4642I | 82 | X | 2 | 35 | 37 | Complexity in the light curves and spectra of slow-evolving superluminous supernovae. | INSERRA C., NICHOLL M., CHEN T.-W., et al. | ||
2017ApJ...845...85L | 342 | D | X C | 8 | 47 | 77 | Analyzing the largest spectroscopic data set of hydrogen-poor super-luminous supernovae. | LIU Y.-Q., MODJAZ M. and BIANCO F.B. | |
2017MNRAS.469.4705C | 82 | X | 2 | 6 | 6 | Spatially resolved analysis of superluminous supernovae PTF 11hrq and PTF 12dam host galaxies. | CIKOTA A., DE CIA A., SCHULZE S., et al. | ||
2017ApJ...848....6Y | 1303 | K A | D | X C | 32 | 23 | 91 | Hydrogen-poor superluminous supernovae with late-time Hα emission: three events from the intermediate Palomar Transient Factory. | YAN L., LUNNAN R., PERLEY D.A., et al. |
2017ApJ...850...55N | 142 | D | X | 4 | 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. | |
2017ApJ...851...95S | 17 | D | 1 | 24 | 24 | Magnetar-powered superluminous supernovae must first be exploded by jets. | SOKER N. and GILKIS A. | ||
2018ApJ...854..175I | 428 | D | X C | 10 | 48 | 19 | A statistical approach to identify superluminous supernovae and probe their diversity. | INSERRA C., PRAJS S., GUTIERREZ C.P., et al. | |
2018MNRAS.475.1046I | 210 | X C F | 3 | 23 | 103 | On the nature of hydrogen-rich superluminous supernovae. | INSERRA C., SMARTT S.J., GALL E.E.E., et al. | ||
2018ApJ...856...59L | 83 | X | 2 | 7 | 11 | A multiple ejecta-circumstellar medium interaction model and its implications for superluminous supernovae iPTF15esb and iPTF13dcc. | LIU L.-D., WANG L.-J., WANG S.-Q., 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...860..100D | 471 | D | X | 12 | 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...864...45M | 223 | D | X | 6 | 37 | 58 | Results from a systematic survey of X-ray emission from hydrogen-poor superluminous SNe. | MARGUTTI R., CHORNOCK R., METZGER B.D., et al. | |
2018ApJ...865....9B | 41 | X | 1 | 18 | 9 | The Type I superluminous supernova PS16aqv: lightcurve complexity and deep limits on radioactive ejecta in a fast event. | BLANCHARD P.K., NICHOLL M., BERGER E., et al. | ||
2018NatAs...2..887L | 1 | 14 | 14 | A UV resonance line echo from a shell around a hydrogen-poor superluminous supernova. | LUNNAN R., FRANSSON C., VREESWIJK P.M., et al. | ||||
2018ApJ...867L..31C | 84 | X | 2 | 16 | 40 | SN 2017ens: the metamorphosis of a luminous broadlined Type Ic supernova into an SN IIn. | CHEN T.-W., INSERRA C., FRASER M., 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. | ||
2019ApJ...874...68C | 17 | D | 1 | 32 | 1 | A systematic study of superluminous supernova light-curve models using clustering. | CHATZOPOULOS E. and TUMINELLO R. | ||
2019A&A...624A.143K | 85 | X | 2 | 64 | 71 | Highly luminous supernovae associated with gamma-ray bursts. I. GRB 111209A/SN 2011kl in the context of stripped-envelope and superluminous supernovae. | KANN D.A., SCHADY P., OLIVARES F.E., et al. | ||
2019RAA....19...63W | 209 | X C | 4 | 28 | 3 | The Energy Sources of Superluminous Supernovae. | WANG S.-Q., WANG L.-J. and DAI Z.-G. | ||
2019MNRAS.487.2215A | 44 | X | 1 | 26 | 67 | Superluminous supernovae from the Dark Energy Survey. | ANGUS C.R., SMITH M., SULLIVAN M., et al. | ||
2019MNRAS.489.1110W | 42 | X | 1 | 6 | ~ | Broad-lined type Ic supernova iPTF16asu: A challenge to all popular models. | WANG L.J., WANG X.F., CANO Z., et al. | ||
2020ApJ...891...98L | 43 | X | 1 | 16 | ~ | The energy sources of double-peaked superluminous supernova PS1-12cil and luminous supernova SN 2012aa. | LI L., WANG S.-Q., LIU L.-D., et al. | ||
2020ApJ...892...28K | 85 | X | 2 | 20 | ~ | SN 2010kd: photometric and spectroscopic analysis of a slow-decaying superluminous supernova. | KUMAR A., PANDEY S.B., KONYVES-TOTH R., 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. | ||
2020MNRAS.497..318L | 553 | X C F | 11 | 15 | ~ | SN 2018hti: a nearby superluminous supernova discovered in a metal-poor galaxy. | LIN W.L., WANG X.F., LI W.X., 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 | 60 | D | X | 2 | 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 | 2 | 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 | 87 | X | 2 | 51 | 12 | SN 2020ank: a bright and fast-evolving H-deficient superluminous supernova. | KUMAR A., KUMAR B., PANDEY S.B., et al. | ||
2021MNRAS.504L..51S | 174 | X | 4 | 7 | ~ | Binary pathways to SLSNe-I: SN 2017gci. | STEVANCE H.F. and ELDRIDGE J.J. | ||
2021MNRAS.504.2073K | 45 | X | 1 | 35 | 51 | A cool and inflated progenitor candidate for the Type Ib supernova 2019yvr at 2.6 yr before explosion. | KILPATRICK C.D., DROUT M.R., AUCHETTL K., et al. | ||
2021ApJ...913..143G | 44 | X | 1 | 20 | 17 | The luminous and double-peaked Type Ic Supernova 2019stc: evidence for multiple energy sources. | GOMEZ S., BERGER E., HOSSEINZADEH G., et al. | ||
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. | ||
2022MNRAS.510.3701S | 45 | X | 1 | 17 | 15 | An environmental analysis of the Type Ib SN 2019yvr and the possible presence of an inflated binary companion. | SUN N.-C., MAUND J.R., CROWTHER P.A., et al. | ||
2022MNRAS.512.4484F | 582 | X C F | 11 | 24 | 4 | Close, bright, and boxy: the superluminous SN 2018hti. | FIORE A., BENETTI S., NICHOLL M., et al. | ||
2022MNRAS.513.2965H | 90 | X | 2 | 12 | ~ | Two years of optical and NIR observations of the superluminous supernova UID 30901 discovered by the UltraVISTA SN survey. | HUEICHAPAN E.D., CONTRERAS C., CARTIER R., et al. | ||
2022ApJ...938...84D | 45 | X | 1 | 34 | 6 | Radio Analysis of SN2004C Reveals an Unusual CSM Density Profile as a Harbinger of Core Collapse. | DEMARCHI L., MARGUTTI R., DITTMAN J., et al. | ||
2022A&A...666A..30P | 448 | X C | 9 | 43 | 14 | SN 2018bsz: A Type I superluminous supernova with aspherical circumstellar material. | PURSIAINEN M., LELOUDAS G., PARASKEVA E., et al. | ||
2022ApJ...940...69K | 108 | D | X | 3 | 32 | 2 | Premaximum Spectroscopic Diversity of Hydrogen-poor Superluminous Supernovae. | KONYVES-TOTH R. | |
2022ApJ...939..105B | 332 | D | S X | 7 | 121 | 10 | Seven Years of Coordinated Chandra-NuSTAR Observations of SN 2014C Unfold the Extreme Mass-loss History of Its Stellar Progenitor. | BRETHAUER D., MARGUTTI R., MILISAVLJEVIC D., et al. | |
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. | ||
2023NatAs...7..779L | 47 | X | 1 | 16 | ~ | A superluminous supernova lightened by collisions with pulsational pair-instability shells. | LIN W., WANG X., YAN L., et al. | ||
2023ApJ...954...44K | 19 | D | 1 | 29 | ~ | Type W and Type 15bn Subgroups of Hydrogen-poor Superluminous Supernovae: Premaximum Diversity, Postmaximum Homogeneity? | KONYVES-TOTH R. and SELI B. | ||
2020RNAAS...4..235B | 43 | X | 1 | 4 | ~ | Six Years of Luminous X-Ray Emission from the Strongly Interacting Type-Ib SN2014C Captured by Chandra and NuSTAR. | BRETHAUER D., MARGUTTI R., MILISAVLJEVIC D., et al. | ||
2023ApJ...954L..45M | 47 | X | 1 | 14 | ~ | Luminous Radio Emission from the Superluminous Supernova 2017ens at 3.3 yr after Explosion. | MARGUTTI R., BRIGHT J.S., MATTHEWS D.J., et al. | ||
2023MNRAS.526.1822K | 112 | D | F | 2 | 31 | ~ | Reduction of supernova light curves by vector Gaussian processes. | KORNILOV M.V., SEMENIKHIN T.A. and PRUZHINSKAYA M.V. | |
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. | ||
2024Natur.625..253C | 50 | X | 1 | 33 | ~ | A 12.4-day periodicity in a close binary system after a supernova. | CHEN P., GAL-YAM A., SOLLERMAN J., et al. |