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| SN 2014ft , the SIMBAD biblio (49 results) | C.D.S. - SIMBAD4 rel 1.8 - 2024.04.23CEST18:42:03 |
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trying to find the most relevant references on this object.
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| 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 |
|---|---|---|---|---|---|---|---|---|---|
2018Sci...362..201D 
|
2 | 34 | 79 | A hot and fast ultra-stripped supernova that likely formed a compact neutron star binary. | DE K., KASLIWAL M.M., OFEK E.O., et al. | ||||
| 2019MNRAS.484.3307M | 64 | X | 1 | 6 | 134 | Three-dimensional simulations of neutrino-driven core-collapse supernovae from low-mass single and binary star progenitors. | MULLER B., TAURIS T.M., HEGER A., et al. | ||
| 2019ApJ...878...49W | 411 | A | X | 9 | 3 | 158 | The evolution of massive helium stars, including mass loss. | WOOSLEY S.E. | |
| 2019PASP..131g8001G | 105 | X | 2 | 21 | 454 | The Zwicky Transient Facility: science objectives. | GRAHAM M.J., KULKARNI S.R., BELLM E.C., et al. | ||
| 2019ApJ...882...93H | 527 | T A | X | 12 | 5 | ~ |
The rate of iPTF 14gqr like ultra-stripped supernovae and binary evolution leading to double neutron star formation. |
HIJIKAWA K., KINUGAWA T., YOSHIDA T., et al. | |
| 2019ApJ...885L..23M | 43 | X | 1 | 14 | 25 | SN2018kzr: a rapidly declining transient from the destruction of a white dwarf. | McBRIEN O.R., SMARTT S.J., CHEN T.-W., et al. | ||
| 2019ApJ...887..127I | 84 | X | 2 | 8 | 2 | On the origin of SN 2016hil - A Type II supernova in the remote outskirts of an elliptical host. | IRANI I., SCHULZE S., GAL-YAM A., et al. | ||
|
2019ApJ...887..169H
|
253 | X C | 5 | 23 | 59 | Evidence for late-stage eruptive mass loss in the progenitor to SN2018gep, a broad-lined IC supernova: pre-explosion emission and a rapidly rising luminous transient. | HO A.Y.Q., GOLDSTEIN D.A., SCHULZE S., et al. | ||
| 2020MNRAS.492.2208C | 60 | D | X | 2 | 39 | ~ | LSQ13ddu: a rapidly evolving stripped-envelope supernova with early circumstellar interaction signatures. | CLARK P., MAGUIRE K., INSERRA C., et al. | |
| 2020ApJ...889L...6C | 43 | X | 1 | 35 | 22 | The most rapidly declining Type I supernova 2019bkc/ATLAS19dqr. | CHEN P., DONG S., STRITZINGER M.D., et al. | ||
| 2020ApJ...890...51E | 64 | X | 1 | 6 | 127 | The explosion of helium stars evolved with mass loss. | ERTL T., WOOSLEY S.E., SUKHBOLD T., et al. | ||
| 2020ApJ...890L..26K | 85 | C | 2 | 10 | ~ | Rapid transients originating from thermonuclear explosions in helium white dwarf tidal disruption events. | KAWANA K., MAEDA K., YOSHIDA N., et al. | ||
| 2020A&A...634A..21S | 43 | X | 1 | 24 | ~ | The Carnegie Supernova Project II. Early observations and progenitor constraints of the Type Ib supernova LSQ13abf. | STRITZINGER M.D., TADDIA F., HOLMBO S., et al. | ||
| 2020A&A...635A.186P | 698 | D | X C | 16 | 33 | ~ | The rise and fall of an extraordinary Ca-rich transient. The discovery of ATLAS19dqr/SN 2019bkc. | PRENTICE S.J., MAGUIRE K., FLORS A., et al. | |
| 2020MNRAS.494.5576P | 128 | X | 3 | 24 | ~ | The mystery of photometric twins DES17X1boj and DES16E2bjy. | PURSIAINEN M., GUTIERREZ C.P., WISEMAN P., et al. | ||
| 2020ApJ...898..158M | 570 | D | X C | 13 | 4 | ~ | Radio emission from ultra-stripped supernovae as diagnostics for properties of the remnant double neutron star binaries. | MATSUOKA T. and MAEDA K. | |
| 2020MNRAS.497..246G | 299 | X C F | 5 | 14 | 14 | AT2018kzr: the merger of an oxygen-neon white dwarf and a neutron star or black hole. | GILLANDERS J.H., SIM S.A. and SMARTT S.J. | ||
|
2020ApJ...900...46Y
|
1210 | D | X C | 28 | 33 | 40 | SN2019dge: a helium-rich ultra-stripped envelope supernova. | YAO Y., DE K., KASLIWAL M.M., et al. | |
| 2020A&A...643A..79S | 43 | X | 1 | 24 | 20 | Two stripped envelope supernovae with circumstellar interaction. But only one really shows it. | SOLLERMAN J., FRANSSON C., BARBARINO C., et al. | ||
|
2020ApJ...905...58D
|
43 | X | 1 | 68 | 64 | The Zwicky Transient Facility Census of the Local Universe. I. Systematic search for calcium-rich gap transients reveals three related spectroscopic subclasses. | DE K., KASLIWAL M.M., TZANIDAKIS A., et al. | ||
| 2021MNRAS.500.4213M | 87 | X | 2 | 33 | ~ | PS15cey and PS17cke: prospective candidates from the Pan-STARRS Search for kilonovae. | McBRIEN O.R., SMARTT S.J., HUBER M.E., et al. | ||
| 2021ApJ...906....3W | 45 | X | 1 | 21 | 41 | A diversity of wave-driven presupernova outbursts. | WU S. and FULLER J. | ||
| 2021ApJ...907L..18D | 133 | X | 3 | 9 | 19 | The peculiar Ca-rich SN2019ehk: evidence for a Type IIb core-collapse supernova from a low-mass stripped progenitor. | DE K., FREMLING U.C., GAL-YAM A., et al. | ||
| 2021MNRAS.502.3385M | 61 | D | X | 2 | 44 | ~ | Limits on mass outflow from optical tidal disruption events. | MATSUMOTO T. and PIRAN T. | |
| 2021ApJ...909..209P | 47 | X | 1 | 8 | 31 | Shock cooling emission from extended material revisited. | PIRO A.L., HAYNIE A. and YAO Y. | ||
| 2021ApJ...912...30N | 2308 | A | D | X C | 53 | 12 | 20 | Calcium-rich transient SN 2019ehk in a star-forming environment: yet another candidate for a precursor of a double neutron-star binary. | NAKAOKA T., MAEDA K., YAMANAKA M., 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. | ||
|
2021A&A...651A..81B
|
366 | D | X C | 8 | 53 | 18 | Type Ic supernovae from the (intermediate) Palomar Transient Factory. | BARBARINO C., SOLLERMAN J., TADDIA F., et al. | |
| 2021ApJ...920L..36J | 44 | X | 1 | 9 | 8 | Novel model of an ultra-stripped supernova progenitor of a double neutron star. | JIANG L., TAURIS T.M., CHEN W.-C., et al. | ||
| 2022MNRAS.509.1557C | 90 | X | 2 | 62 | 13 | Formation and evolution of binary neutron stars: mergers and their host galaxies. | CHU Q., YU S. and LU Y. | ||
| 2021ApJ...923...41L | 87 | X | 2 | 17 | 16 | Wave-driven mass loss of stripped envelope massive stars: progenitor-dependence, mass ejection, and supernovae. | LEUNG S.-C., WU S. and FULLER J. | ||
| 2022MNRAS.512.5782S | 90 | X | 2 | 30 | 4 | The High Time Resolution Universe Pulsar Survey - XVII. PSR J1325-6253, a low eccentricity double neutron star system from an ultra-stripped supernova. | SENGAR R., BALAKRISHNAN V., STEVENSON S., et al. | ||
| 2022ApJ...927..223S | 1014 | A | X C | 22 | 3 | 7 | On the Energy Source of Ultrastripped Supernovae. | SAWADA R., KASHIYAMA K. and SUWA Y. | |
| 2022ApJ...928..114W | 91 | C | 1 | 6 | 7 | iPTF 16asu Revisited: A Rapidly Evolving Superluminous Broad-lined Ic Supernova?. | WANG S.-Q. and GAN W.-P. | ||
|
2022Natur.601..201G
|
47 | X | 1 | 21 | 45 | A WC/WO star exploding within an expanding carbon-oxygen-neon nebula. | GAL-YAM A., BRUCH R., SCHULZE S., et al. | ||
| 2022ApJ...930..143M | 90 | X | 2 | 24 | 1 | Long-term Evolution of a Supernova Remnant Hosting a Double Neutron Star Binary. | MATSUOKA T., LEE S.-H., MAEDA K., et al. | ||
| 2022ApJ...932...58J | 45 | X | 1 | 29 | 14 | The Circumstellar Environments of Double-peaked, Calcium-strong Transients 2021gno and 2021inl. | JACOBSON-GALAN W.V., VENKATRAMAN P., MARGUTTI R., et al. | ||
| 2022ApJ...935...86K | 179 | X | 4 | 6 | 1 | X-Raying the Birth of Binary Neutron Stars and Neutron Star-Black Hole Binaries. | KASHIYAMA K., SAWADA R. and SUWA Y. | ||
| 2022ApJ...938...73P | 180 | X C | 3 | 16 | 19 | The Diverse Properties of Type Icn Supernovae Point to Multiple Progenitor Channels. | PELLEGRINO C., HOWELL D.A., TERRERAN G., et al. | ||
| 2022ApJ...940L..27W | 314 | X | 7 | 11 | 5 | Extreme Mass Loss in Low-mass Type Ib/c Supernova Progenitors. | WU S.C. and FULLER J. | ||
| 2022A&A...667A..92O | 18 | D | 2 | 25 | 2 | Supernova double-peaked light curves from double-nickel distribution. | ORELLANA M. and BERSTEN M.C. | ||
| 2023MNRAS.518..623M | 94 | X | 2 | 4 | 7 | Bare collapse, formation of neutron star binaries and fast optical transients. | MOR R., LIVNE E. and PIRAN T. | ||
| 2023ApJ...952...86S | 485 | D | X C | 10 | 14 | 2 | SN2019wxt: An Ultrastripped Supernova Candidate Discovered in the Electromagnetic Follow-up of a Gravitational Wave Trigger. | SHIVKUMAR H., JAODAND A.D., BALASUBRAMANIAN A., et al. | |
| 2023A&A...675A..82S | 47 | X | 1 | 54 | ~ | The Carnegie Supernova Project I Optical spectroscopy of stripped-envelope supernovae. | STRITZINGER M.D., HOLMBO S., MORRELL N., et al. | ||
| 2023A&A...675A.201A | 467 | X | 10 | 26 | ~ | Panning for gold, but finding helium: Discovery of the ultra-stripped supernova SN 2019wxt from gravitational-wave follow-up observations. | AGUDO I., AMATI L., AN T., et al. | ||
| 2023MNRAS.526..279E | 345 | D | X C | 7 | 22 | ~ | SN 2021gno: a calcium-rich transient with double-peaked light curves. | ERTINI K., FOLATELLI G., MARTINEZ L., et al. | |
| 2023A&A...678A..87K | 299 | D | X | 7 | 59 | ~ | A population of Type Ibc supernovae with massive progenitors Broad lightcurves not uncommon in (i)PTF. | KARAMEHMETOGLU E., SOLLERMAN J., TADDIA F., et al. | |
| 2023ApJ...959L..32Y | 812 | D | X C | 17 | 26 | ~ | Discovery of the Closest Ultra-stripped Supernova: SN 2021agco in UGC 3855. | YAN S., WANG X., GAO X., et al. | |
| 2024ApJ...962..109I | 950 | X C | 18 | 22 | ~ | SN 2022oqm-A Ca-rich Explosion of a Compact Progenitor Embedded in C/O Circumstellar Material. | IRANI I., CHEN P., MORAG J., et al. |
