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| SN 2015F , the SIMBAD biblio (79 results) | C.D.S. - SIMBAD4 rel 1.8 - 2024.05.14CEST09:46:22 |
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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 |
|---|---|---|---|---|---|---|---|---|---|
| 2015ApJS..221...22I | 1431 | T A | D | S X C | 34 | 12 | 26 |
The very early light curve of SN 2015F in NGC 2442: a possible detection of shock-heated cooling emission and constraints on SN Ia progenitor system. |
IM M., CHOI C., YOON S.-C., et al. |
| 2015ATel.7209....1F | 16 | D | 1 | 6 | 6 | PESSTO spectroscopic classification of optical transients. | FRASER M., SMITH M., FIRTH R., et al. | ||
| 2015ATel.7220....1F | 119 | T | X | 2 | 1 | 1 |
HST Observations of PSN J07361576-6930230. |
FOLEY R.J. | |
| 2015ATel.7711....1C | 40 | X | 1 | 5 | 1 | SkyMapper Discovery of a Nearby SN IIn. | CHILDRESS M., SCALZO R., YUAN F., et al. | ||
| 2016MNRAS.461.1308F | 378 | K | D | X F | 9 | 16 | 22 | Ultraviolet diversity of Type Ia Supernovae. | FOLEY R.J., PAN Y., BROWN P., et al. |
2017ApJ...836..232B 
|
219 | D | X C | 5 | 34 | 3 | Reddened, redshifted, or intrinsically red? Understanding near-ultraviolet colors of Type Ia supernovae. | BROWN P.J., LANDEZ N.J., MILNE P.A., et al. | |
| 2017MNRAS.464.4476C | 5037 | T K A | D | S X C F | 121 | 18 | 32 |
Early observations of the nearby Type Ia supernova SN 2015F. |
CARTIER R., SULLIVAN M., FIRTH R.E., et al. |
|
2017ApJ...841...48S
|
44 | X | 1 | 10 | 34 | Whimper of a bang: documenting the final days of the nearby Type Ia supernova 2011fe. | SHAPPEE B.J., STANEK K.Z., KOCHANEK C.S., et al. | ||
| 2017ApJ...841...64Z | 41 | X | 1 | 40 | 13 | Discovery and follow-up observations of the young Type Ia supernova 2016coj. | ZHENG W., FILIPPENKO A.V., MAUERHAN J., et al. | ||
|
2017MNRAS.467.1098H
|
16 | D | 1 | 284 | 22 | The ASAS-SN bright supernova catalogue - II. 2015. | HOLOIEN T.W.-S., BROWN J.S., STANEK K.Z., et al. | ||
| 2017Natur.550...80J | 6 | 16 | 98 | A hybrid type Ia supernova with an early flash triggered by helium-shell detonation. | JIANG J.-A., DOI M., MAEDA K., et al. | ||||
| 2018ApJ...852...89Y | 43 | X | 1 | 7 | 17 | Late-time flattening of Type Ia supernova light curves: constraints from SN 2014J in M82. | YANG Y., WANG L., BAADE D., et al. | ||
| 2017MNRAS.472.2787N | 44 | X | 1 | 9 | 32 | Early light curves for Type Ia supernova explosion models. | NOEBAUER U.M., KROMER M., TAUBENBERGER S., et al. | ||
| 2017MNRAS.472.3437G | 1683 | K | D | S X C F | 39 | 24 | 49 | Nebular-phase spectra of nearby Type Ia Supernovae. | GRAHAM M.L., KUMAR S., HOSSEINZADEH G., et al. |
| 2018MNRAS.474..411B | 99 | D | X | 3 | 47 | 12 | GRAWITA: VLT Survey Telescope observations of the gravitational wave sources GW150914 and GW151226. | BROCATO E., BRANCHESI M., CAPPELLARO E., et al. | |
| 2018MNRAS.473.4805K | 41 | X | 1 | 37 | 12 | Connecting the progenitors, pre-explosion variability and giant outbursts of luminous blue variables with Gaia16cfr. | KILPATRICK C.D., FOLEY R.J., DROUT M.R., et al. | ||
| 2018A&A...609A..72D | 100 | D | C | 3 | 82 | 145 | Measuring the Hubble constant with Type Ia supernovae as near-infrared standard candles. | DHAWAN S., JHA S.W. and LEIBUNDGUT B. | |
| 2018ApJ...855....6S | 44 | X | 1 | 14 | 44 | Strong evidence against a non-degenerate companion in SN 2012cg. | SHAPPEE B.J., PIRO A.L., STANEK K.Z., et al. | ||
| 2018ApJ...857...88J | 207 | X | 5 | 8 | 8 | Constraining Type Ia supernova progenitor scenarios with extremely late-time photometry of supernova SN 2013aa. | JACOBSON-GALAN W.V., DIMITRIADIS G., FOLEY R.J., et al. | ||
| 2018ApJ...859...79G | 2429 | T K A | D | S X C | 57 | 13 | 15 |
Observations of SN 2015F suggest a correlation between the intrinsic luminosity of Type Ia supernovae and the shape of their light curves >900 days after explosion. |
GRAUR O., ZUREK D.R., REST A., et al. |
|
2018A&A...614A..71N
|
41 | X | 1 | 102 | 5 | Understanding type Ia supernovae through their U-band spectra. | NORDIN J., ALDERING G., ANTILOGUS P., et al. | ||
| 2018ApJ...863..176M | 247 | X C | 5 | 9 | 2 | Nucleosynthesis constraints on the explosion mechanism for Type Ia supernovae. | MORI K., FAMIANO M.A., KAJINO T., et al. | ||
| 2018ApJ...864L..35S | 17 | D | 1 | 26 | 51 | Red versus blue: early observations of thermonuclear supernovae reveal two distinct populations? | STRITZINGER M.D., SHAPPEE B.J., PIRO A.L., et al. | ||
| 2018ApJ...865..149J | 99 | D | C | 2 | 54 | 13 | Surface radioactivity or interactions? Multiple origins of early-excess Type Ia supernovae and associated subclasses. | JIANG J.-A., DOI M., MAEDA K., et al. | |
| 2018ApJ...866...10G | 123 | X | 3 | 7 | 5 | Late-time observations of ASASSN-14lp strengthen the case for a correlation between the peak luminosity of Type Ia supernovae and the shape of their late-time light curves. | GRAUR O., ZUREK D.R., CARA M., et al. | ||
| 2018ApJ...867...56B | 16 | D | 1 | 29 | 3 | The UltraViolet colors of Type Ia supernovae and their photospheric velocities. | BROWN P.J., PERRY J.M., BEENY B.A., et al. | ||
|
2018ApJ...867..108J
|
41 | X | 1 | 274 | 106 | Should Type Ia supernova distances be corrected for their local environments? | JONES D.O., RIESS A.G., SCOLNIC D.M., et al. | ||
| 2018MNRAS.481..878Z | 165 | C F | 4 | 31 | 4 | SN 2014J in M82: new insights on the spectral diversity of Type Ia supernovae. | ZHANG K., WANG X., ZHANG J., et al. | ||
|
2018ApJ...869...56B
|
412 | A | D | X C | 10 | 176 | 128 | The Carnegie Supernova Project: absolute calibration and the Hubble constant. | BURNS C.R., PARENT E., PHILLIPS M.M., et al. |
|
2019ApJ...870...13S
|
46 | X | 1 | 17 | 71 | Seeing double: ASASSN-18bt exhibits a two-component rise in the early-time K2 light curve. | SHAPPEE B.J., HOLOIEN T.W.-S., DROUT M.R., et al. | ||
| 2019ApJ...870...14G | 268 | D | X | 7 | 7 | 6 | Late-time observations of the Type Ia supernova SN 2014J with the Hubble Space Telescope Wide Field Camera 3. | GRAUR O. | |
| 2019ApJ...871...62G | 17 | D | 3 | 91 | 36 | Delayed circumstellar interaction for Type Ia SN 2015cp revealed by an HST ultraviolet imaging survey. | GRAHAM M.L., HARRIS C.E., NUGENT P.E., et al. | ||
| 2019PASP..131a4001P | 59 | D | X | 2 | 416 | 58 | Carnegie Supernova Project-II: extending the near-infrared Hubble diagram for Type Ia supernovae to z ∼ 0.1. | PHILLIPS M.M., CONTRERAS C., HSIAO E.Y., et al. | |
|
2019PASP..131a4002H
|
17 | D | 2 | 173 | 56 | Carnegie Supernova Project-II: the near-infrared spectroscopy program. | HSIAO E.Y., PHILLIPS M.M., MARION G.H., et al. | ||
|
2019MNRAS.484.3785B
|
17 | D | 1 | 918 | 27 | The relative specific Type Ia supernovae rate from three years of ASAS-SN. | BROWN J.S., STANEK K.Z., HOLOIEN T.W.-S., et al. | ||
|
2019ApJ...877..152B
|
169 | X C | 3 | 10 | 24 | Red and reddened: ultraviolet through near-infrared observations of Type Ia supernova 2017erp. | BROWN P.J., HOSSEINZADEH G., JHA S.W., et al. | ||
|
2019A&A...627A.174H
|
42 | X | 1 | 19 | 15 | Discovery and progenitor constraints on the Type Ia supernova 2013gy. | HOLMBO S., STRITZINGER M.D., SHAPPEE B.J., et al. | ||
|
2019ApJ...882...30L
|
209 | X C | 4 | 15 | ~ | Observations of Type Ia supernova 2014J for nearly 900 days and constraints on its progenitor system. | LI W., WANG X., HU M., et al. | ||
| 2019ApJ...882...34F | 25 | D | 1 | 70 | 582 | The Carnegie-Chicago Hubble Program. VIII. An independent determination of the Hubble constant based on the tip of the red giant branch. | FREEDMAN W.L., MADORE B.F., HATT D., et al. | ||
|
2020MNRAS.491.2902F
|
783 | K | D | X C | 18 | 68 | 46 | Sub-Chandrasekhar progenitors favoured for Type Ia supernovae: evidence from late-time spectroscopy. | FLORS A., SPYROMILIO J., TAUBENBERGER S., et al. |
| 2020MNRAS.491.5897P | 400 | D | X C | 9 | 59 | ~ | Swift UVOT grism observations of nearby Type Ia supernovae - II. Probing the progenitor metallicity of SNe Ia with ultraviolet spectra. | PAN Y.-C., FOLEY R.J., JONES D.O., et al. | |
| 2020MNRAS.492.3553V | 17 | D | 2 | 56 | 6 | Signatures of bimodality in nebular phase Type Ia supernova spectra. | VALLELY P.J., TUCKER M.A., SHAPPEE B.J., et al. | ||
|
2020A&A...634A..37M
|
145 | D | X | 4 | 35 | 32 | Determining the 56Ni distribution of type Ia supernovae from observations within days of explosion. | MAGEE M.R., MAGUIRE K., KOTAK R., et al. | |
| 2020ApJ...892..142H | 170 | X | 4 | 24 | ~ | SN 2017cfd: a normal Type Ia supernova discovered very young. | HAN X., ZHENG W., STAHL B.E., et al. | ||
| 2020NatAs...4..188G | 85 | C | 1 | 21 | 17 | A year-long plateau in the late-time near-infrared light curves of type Ia supernovae. | GRAUR O., MAGUIRE K., RYAN R., et al. | ||
|
2020MNRAS.493.1044T
|
187 | D | X C | 4 | 116 | 49 | Nebular spectra of 111 Type Ia supernovae disfavour single-degenerate progenitors. | TUCKER M.A., SHAPPEE B.J., VALLELY P.J., et al. | |
| 2020ApJ...895L...3A | 17 | D | 1 | 142 | ~ | Carnegie supernova Project-II: a new method to photometrically identify sub-types of extreme Type Ia supernovae. | ASHALL C., LU J., BURNS C., et al. | ||
| 2017ATel.9938....1F | 81 | X | 2 | 4 | ~ | PESSTO classification and characterisation of AT 2016jbu / Gaia16cfr. | FRASER M., PASTORELLO A., CARTIER R., et al. | ||
| 2020MNRAS.496.4517S | 17 | D | 1 | 46 | 22 | The γ-ray deposition histories of core-collapse supernovae. | SHARON A. and KUSHNIR D. | ||
| 2020ApJS..250...12C | 485 | D | S X C | 10 | 39 | ~ | Artificial intelligence-assisted inversion (AIAI) of synthetic Type Ia supernova spectra. | CHEN X., HU L. and WANG L. | |
|
2020MNRAS.499.1424H
|
17 | D | 1 | 408 | ~ | Supernovae and their host galaxies - VII. The diversity of Type Ia supernova progenitors. | HAKOBYAN A.A., BARKHUDARYAN L.V., KARAPETYAN A.G., et al. | ||
| 2020ApJ...904...29M | 43 | X | 1 | 6 | ~ | Screening effects on electron capture rates and Type Ia supernova nucleosynthesis. | MORI K., SUZUKI T., HONMA M., et al. | ||
| 2021MNRAS.500.1095H | 192 | D | X | 5 | 55 | 5 | The value of the Hubble-Lemaitre constant queried by Type Ia supernovae: a journey from the Calan-Tololo Project to the Carnegie Supernova Program. | HAMUY M., CARTIER R., CONTRERAS C., et al. | |
| 2021ApJ...909..152L | 44 | X | 1 | 13 | ~ | Exploration of aspherical ejecta properties in Type Ia supernovae: progenitor dependence and applications to progenitor classification. | LEUNG S.-C., DIEHL R., NOMOTO K., et al. | ||
| 2021A&A...647A..72K | 18 | D | 1 | 68 | 81 | A new measurement of the Hubble constant using Type Ia supernovae calibrated with surface brightness fluctuations. | KHETAN N., IZZO L., BRANCHESI M., et al. | ||
| 2021PASP..133d4002B | 17 | D | 2 | 142 | ~ | Low-redshift Type Ia supernova from the LSQ/LCO collaboration. | BALTAY C., GROSSMAN L., HOWARD R., et al. | ||
|
2021MNRAS.505L..52H
|
17 | D | 1 | 189 | ~ | Type Ia supernovae in the star formation deserts of spiral host galaxies. | HAKOBYAN A.A., KARAPETYAN A.G., BARKHUDARYAN L.V., et al. | ||
| 2021MNRAS.508.1590P | 44 | X | 1 | 13 | ~ | Prospects of direct detection of 48V gamma-rays from thermonuclear supernovae. | PANTHER F.H., SEITENZAHL I.R., RUITER A.J., et al. | ||
|
2021ApJ...923...86C
|
17 | D | 1 | 813 | 3 | Local environments of low-redshift supernovae. | CRONIN S.A., UTOMO D., LEROY A.K., et al. | ||
|
2021ApJ...923..167W
|
306 | X C | 6 | 9 | 11 | SN 2018agk: a prototypical Type Ia supernova with a smooth power-law rise in Kepler (K2). | WANG Q., REST A., ZENATI Y., et al. | ||
| 2022MNRAS.510.4779S | 18 | D | 2 | 445 | ~ | Type Ia supernova magnitude step from the local dark matter environment. | STEIGERWALD H., RODRIGUES D., PROFUMO S., et al. | ||
| 2022MNRAS.511.3682G | 90 | C | 5 | 34 | 6 | Nebular-phase spectra of Type Ia supernovae from the Las Cumbres Observatory Global Supernova Project. | GRAHAM M.L., KENNEDY T.D., KUMAR S., et al. | ||
|
2022ApJS..259...53C
|
18 | D | 1 | 291 | 15 | The First Data Release of CNIa0.02-A Complete Nearby (Redshift <0.02) Sample of Type Ia Supernova Light Curves. | CHEN P., DONG S., KOCHANEK C.S., et al. | ||
| 2022MNRAS.513.5642B | 358 | X C F | 6 | 19 | 16 | Photometric and spectroscopic evolution of the interacting transient AT 2016jbu(Gaia16cfr). | BRENNAN S.J., FRASER M., JOHANSSON J., et al. | ||
| 2022ApJ...932L...2A | 46 | X | 1 | 16 | 23 | A Speed Bump: SN 2021aefx Shows that Doppler Shift Alone Can Explain Early Excess Blue Flux in Some Type Ia Supernovae. | ASHALL C., LU J., SHAPPEE B.J., et al. | ||
| 2022ApJ...933..172J | 180 | X C | 3 | 24 | 29 | Cosmological Results from the RAISIN Survey: Using Type Ia Supernovae in the Near Infrared as a Novel Path to Measure the Dark Energy Equation of State. | JONES D.O., MANDEL K.S., KIRSHNER R.P., et al. | ||
| 2022ApJ...934L...7R | 24 | D | 1 | 105 | 637 | A Comprehensive Measurement of the Local Value of the Hubble Constant with 1 km s–1 Mpc–1 Uncertainty from the Hubble Space Telescope and the SH0ES Team. | RIESS A.G., YUAN W., MACRI L.M., et al. | ||
| 2022ApJ...935...58M | 91 | F | 2 | 22 | 34 | The Hubble Tension Revisited: Additional Local Distance Ladder Uncertainties. | MORTSELL E., GOOBAR A., JOHANSSON J., et al. | ||
| 2022MNRAS.515.3703T | 986 | A | D | X C F | 21 | 14 | 4 | The late-time light curves of Type Ia supernovae: confronting models with observations. | TIWARI V., GRAUR O., FISHER R., et al. |
| 2022ApJ...938..113S | 51 | X | 1 | 19 | 125 | The Pantheon+ Analysis: The Full Data Set and Light-curve Release. | SCOLNIC D., BROUT D., CARR A., et al. | ||
| 2022ApJ...941L..33A | 45 | X | 1 | 21 | 1 | White Dwarf-Red Giant Star Binaries as Type Ia Supernova Progenitors: With and without Magnetic Confinement. | ABLIMIT I., PODSIADLOWSKI P., DI STEFANO R., et al. | ||
| 2023ApJ...944L...3K | 421 | X | 9 | 9 | 11 | A JWST Near- and Mid-infrared Nebular Spectrum of the Type Ia Supernova 2021aefx. | KWOK L.A., JHA S.W., TEMIM T., et al. | ||
| 2023MNRAS.522.3481D | 439 | D | X F | 9 | 24 | 3 | SN 2021fxy: mid-ultraviolet flux suppression is a common feature of Type Ia supernovae. | DERKACY J.M., PAUGH S., BARON E., et al. | |
| 2023ApJ...949...33L | 47 | X | 1 | 25 | 3 | The Early Light Curve of the Type Ia Supernova 2021hpr in NGC 3147: Progenitor Constraints with the Companion Interaction Model. | LIM G., IM M., PAEK G.S.H., et al. | ||
| 2023MNRAS.524..235D | 252 | D | X C F | 4 | 136 | ~ | A BayeSN distance ladder: H0 from a consistent modelling of Type Ia supernovae from the optical to the near-infrared. | DHAWAN S., THORP S., MANDEL K.S., et al. | |
| 2023RAA....23h2001L | 187 | X | 4 | 78 | ~ | Type Ia Supernova Explosions in Binary Systems: A Review. | LIU Z.-W., ROPKE F.K. and HAN Z. | ||
| 2023MNRAS.526.1268L | 345 | D | X F | 7 | 72 | ~ | Implications for the explosion mechanism of Type Ia supernovae from their late-time spectra. | LIU J., WANG X., FILIPPENKO A.V., et al. | |
|
2023A&A...679A..95G
|
112 | D | C | 3 | 152 | ~ | An updated measurement of the Hubble constant from near-infrared observations of Type Ia supernovae. | GALBANY L., DE JAEGER T., RIESS A.G., et al. | |
| 2024ApJ...962..125C | 150 | X C | 2 | 9 | ~ | Artificial Intelligence Assisted Inversion (AIAI): Quantifying the Spectral Features of 56Ni of Type Ia Supernovae. | CHEN X., WANG L., HU L., et al. |
