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SN 2014G , the SIMBAD biblio (62 results) | C.D.S. - SIMBAD4 rel 1.8 - 2024.04.25CEST13:45:41 |
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 |
---|---|---|---|---|---|---|---|---|---|
2008yCat....1.2024B | 15 | D | 1 | 54 | 4 | Asiago Supernova Catalogue. | BARBON R., BUONDI V., CAPPELLARO E., et al. | ||
2015MNRAS.448.2608V | 17 | D | 1 | 21 | 53 | Supernova 2013by: a Type IIL supernova with a IIP-like light-curve drop. | VALENTI S., SAND D., STRITZINGER M., et al. | ||
2014ATel.5767....1O | 118 | T | X | 2 | 2 | 3 |
Asiago classification of PSN J10543413+5417569 as a young type-IIn supernova. |
OCHNER P., SIVIERO A., TOMASELLA L., et al. | |
2014ATel.5770....1Z | 79 | T | 1 | 3 | 1 |
KAIT Independent Discovery and Robotic Follow-up Observations of the Young Type-IIn Supernova in NGC 3448: PSN J10543413+5417569. |
ZHENG W., LI W., FILIPPENKO A.V., et al. | ||
2014ATel.5935....1E | 197 | T | X | 4 | 2 | 2 |
SN 2014G is a Type II-L. |
EENMAE T., MARTIN J.C., GRAMMER S., et al. | |
2016MNRAS.455.2712B | 4495 | T K A | D | S X C F | 109 | 40 | 3 | Photometric and polarimetric observations of fast declining Type II supernovae 2013hj and 2014G. | BOSE S., KUMAR B., MISRA K., et al. |
2016MNRAS.459.3939V | 459 | K | D | X C F | 10 | 210 | 225 | The diversity of Type II supernova versus the similarity in their progenitors. | VALENTI S., HOWELL D.A., STRITZINGER M.D., et al. |
2016MNRAS.462..137T | 3293 | T A | D | X C | 81 | 14 | 29 | The multifaceted Type II-L supernova 2014G from pre-maximum to nebular phase. | TERRERAN G., JERKSTRAND A., BENETTI S., et al. |
2017ApJ...841..127M | 344 | D | X C | 8 | 26 | 80 | The nickel mass distribution of normal Type II supernovae. | MULLER T., PRIETO J.L., PEJCHA O., et al. | |
2017MNRAS.470.1881P | 16 | D | 1 | 34 | 6 | Point-source and diffuse high-energy neutrino emission from Type IIn supernovae. | PETROPOULOU M., COENDERS S., VASILOPOULOS G., et al. | ||
2017ApJ...848....5B | 16 | D | 1 | 20 | ~ | The transition of a Type IIL supernova into a supernova remnant: late-time observations of SN 2013by. | BLACK C.S., MILISAVLJEVIC D., MARGUTTI R., et al. | ||
2018MNRAS.474..197P | 83 | C | 1 | 28 | 53 | Supernovae 2016bdu and 2005gl, and their link with SN 2009ip-like transients: another piece of the puzzle. | PASTORELLO A., KOCHANEK C.S., FRASER M., et al. | ||
2018MNRAS.476.1497B | 329 | X C F | 6 | 31 | 9 | SN 2013fs and SN 2013fr: exploring the circumstellar-material diversity in Type II supernovae. | BULLIVANT C., SMITH N., WILLIAMS G.G., et al. | ||
2018ApJ...862..107B | 206 | X C | 4 | 26 | 7 | ASASSN-15nx: a luminous Type II supernova with a "perfect" linear decline. | BOSE S., DONG S., KOCHANEK C.S., et al. | ||
2018MNRAS.480.2475S | 99 | D | C | 2 | 58 | 8 | ASASSN-14dq: a fast-declining Type II-P supernova in a low-luminosity host galaxy. | SINGH A., SRIVASTAV S., KUMAR B., et al. | |
2019MNRAS.483.5459R | 59 | D | X | 2 | 66 | 5 | Type II supernovae as distance indicators at near-IR wavelengths. | RODRIGUEZ O., PIGNATA G., HAMUY M., et al. | |
2019MNRAS.485.5120B | 84 | C | 2 | 20 | 2 | Signatures of circumstellar interaction in the Type IIL supernova ASASSN-15oz. | BOSTROEM K.A., VALENTI S., HORESH A., et al. | ||
2019MNRAS.486.2850D | 125 | X F | 2 | 27 | 3 | SN 2016B a.k.a. ASASSN-16ab: a transitional Type II supernova. | DASTIDAR R., MISRA K., SINGH M., et al. | ||
2019ApJS..241...38S | 17 | D | 4 | 220 | 38 | A comprehensive analysis of Spitzer supernovae. | SZALAI T., ZSIROS S., FOX O.D., et al. | ||
2019MNRAS.488.3089K | 42 | X | 1 | 38 | ~ | On the observational behaviour of the highly polarized Type IIn supernova SN 2017hcc. | KUMAR B., ESWARAIAH C., SINGH A., et al. | ||
2019MNRAS.488.4239P | 17 | D | 3 | 106 | 19 | Comparison of the optical light curves of hydrogen-rich and hydrogen-poor type II supernovae. | PESSI P.J., FOLATELLI G., ANDERSON J.P., et al. | ||
2019MNRAS.489..641M | 17 | D | 1 | 42 | ~ | A comparison of explosion energies for simulated and observed core-collapse supernovae. | MURPHY J.W., MABANTA Q. and DOLENCE J.C. | ||
2019ApJ...885...43A | 42 | X | 1 | 36 | 30 | SN 2017gmr: an energetic Type II-P supernova with asymmetries. | ANDREWS J.E., SAND D.J., VALENTI S., et al. | ||
2019A&A...631A...8H | 1047 | A | D | S X C | 24 | 19 | 38 | Photometric and spectroscopic diversity of Type II supernovae. | HILLIER D.J. and DESSART L. |
2019MNRAS.489.5802V | 17 | D | 1 | 72 | 28 | Spectrophotometric templates for core-collapse supernovae and their application in simulations of time-domain surveys. | VINCENZI M., SULLIVAN M., FIRTH R.E., et al. | ||
2019MNRAS.490.1605D | 209 | X F | 4 | 25 | ~ | SN 2015an: a normal luminosity type II supernova with low expansion velocity at early phases. | DASTIDAR R., MISRA K., VALENTI S., et al. | ||
2019MNRAS.490.2799D | 100 | D | F | 4 | 109 | 41 | The Berkeley sample of Type II supernovae: BVRI light curves and spectroscopy of 55 SNe II. | DE JAEGER T., ZHENG W., STAHL B.E., et al. | |
2020ApJ...890..177K | 128 | X C | 2 | 19 | ~ | A new method to classify Type IIP/IIL supernovae based on their spectra. | KOU S., CHEN X. and LIU X. | ||
2020MNRAS.493.1761R | 639 | X C | 14 | 34 | 9 | SN 2016gsd: an unusually luminous and linear Type II supernova with high velocities. | REYNOLDS T.M., FRASER M., MATTILA S., et al. | ||
2020ApJ...895...31B | 256 | X C | 5 | 14 | 16 | Discovery and rapid follow-up observations of the unusual Type II SN 2018ivc in NGC 1068. | BOSTROEM K.A., VALENTI S., SAND D.J., et al. | ||
2020MNRAS.494.5882R | 213 | X F | 4 | 61 | ~ | Luminous Type II supernovae for their low expansion velocities. | RODRIGUEZ O., PIGNATA G., ANDERSON J.P., et al. | ||
2020MNRAS.496.1325B | 485 | D | X C | 11 | 35 | 19 | Progenitors of early-time interacting supernovae. | BOIAN I. and GROH J.H. | |
2020A&A...641A.177M | 17 | D | 1 | 288 | ~ | Stripped-envelope core-collapse supernova 56Ni masses. Persistently larger values than supernovae type II. | MEZA N. and ANDERSON J.P. | ||
2020MNRAS.499..974G | 511 | X F | 11 | 41 | ~ | SN 2017ivv: two years of evolution of a transitional Type II supernova. | GUTIERREZ C.P., PASTORELLO A., JERKSTRAND A., et al. | ||
2020A&A...642A.214K | 43 | X | 1 | 21 | 15 | Supernova explosions interacting with aspherical circumstellar material: implications for light curves, spectral line profiles, and polarization. | KURFURST P., PEJCHA O. and KRTICKA J. | ||
2021ApJ...907...52T | 45 | X | 1 | 18 | 19 | The early discovery of SN 2017ahn: signatures of persistent interaction in a fast-declining Type II supernova. | TARTAGLIA L., SAND D.J., GROH J.H., et al. | ||
2021MNRAS.503.3472B | 305 | X C | 6 | 36 | 7 | ASASSN-18am/SN 2018gk: an overluminous Type IIb supernova from a massive progenitor. | BOSE S., DONG S., KOCHANEK C.S., et al. | ||
2021MNRAS.504.1009D | 479 | X C F | 9 | 38 | ~ | The optical properties of three Type II supernovae: 2014cx, 2014cy, and 2015cz. | DASTIDAR R., MISRA K., SINGH M., et al. | ||
2021MNRAS.505.1742R | 1019 | D | X C F | 22 | 264 | 9 | The iron yield of normal Type II supernovae. | RODRIGUEZ O., MEZA N., PINEDA-GARCIA J., 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. | ||
2021MNRAS.506.4715R | 148 | D | X | 4 | 92 | 9 | A systematic reclassification of Type IIn supernovae. | RANSOME C.L., HABERGHAM-MAWSON S.M., DARNLEY M.J., et al. | |
2021MNRAS.506.4819P | 1193 | D | X C | 27 | 21 | 3 | SN 2019hcc: a Type II supernova displaying early O II lines. | PARRAG E., INSERRA C., SCHULZE S., et al. | |
2022ApJ...924...15J | 270 | X | 6 | 30 | 53 | Final moments. I. Precursor emission, envelope inflation, and enhanced mass loss preceding the luminous Type II Supernova 2020tlf. | JACOBSON-GALAN W.V., DESSART L., JONES D.O., et al. | ||
2022ApJ...926...20T | 628 | X C | 13 | 16 | 25 | The Early Phases of Supernova 2020pni: Shock Ionization of the Nitrogen-enriched Circumstellar Material. | TERRERAN G., JACOBSON-GALAN W.V., GROH J.H., et al. | ||
2022ApJ...927...10I | 134 | X C | 2 | 34 | 11 | Less Than 1% of Core-collapse Supernovae in the Local Universe Occur in Elliptical Galaxies. | IRANI I., PRENTICE S.J., SCHULZE S., et al. | ||
2022MNRAS.513.4556Z | 18 | D | 2 | 41 | 1 | SN 2019va: a Type IIP Supernova with Large Influence of Nickel-56 Decay on the Plateau-phase Light Curve. | ZHANG X., WANG X., SAI H., et al. | ||
2022ApJ...930...31B | 18 | D | 1 | 90 | 3 | Characterization of Supernovae Based on the Spectral-Temporal Energy Distribution: Two Possible SN Ib Subtypes. | BENGYAT O. and GAL-YAM A. | ||
2022ApJ...930...34T | 403 | X | 9 | 23 | 7 | SN 2020jfo: A Short-plateau Type II Supernova from a Low-mass Progenitor. | TEJA R.S., SINGH A., SAHU D.K., et al. | ||
2022MNRAS.514.5686P | 18 | D | 2 | 87 | 9 | Oxygen and calcium nebular emission line relationships in core-collapse supernovae and Ca-rich transients. | PRENTICE S.J., MAGUIRE K., SIEBENALER L., et al. | ||
2022MNRAS.515..897R | 108 | D | F | 6 | 122 | 8 | Luminosity distribution of Type II supernova progenitors. | RODRIGUEZ O. | |
2022MNRAS.516.1193K | 90 | C | 1 | 34 | 10 | The Zwicky Transient Facility phase I sample of hydrogen-rich superluminous supernovae without strong narrow emission lines. | KANGAS T., YAN L., SCHULZE S., et al. | ||
2023ApJ...949L..12A | 19 | D | 1 | 56 | 3 | Constraining High-energy Neutrino Emission from Supernovae with IceCube. | ABBASI R., ACKERMANN M., ADAMS J., et al. | ||
2023MNRAS.518.5741S | 19 | D | 2 | 22 | 5 | What can Gaussian processes really tell us about supernova light curves? Consequences for Type II(b) morphologies and genealogies. | STEVANCE H.F. and LEE A. | ||
2023MNRAS.519..248A | 187 | X F | 3 | 46 | 3 | Photometric and spectroscopic analysis of the Type II SN 2020jfo with a short plateau. | AILAWADHI B., DASTIDAR R., MISRA K., et al. | ||
2023MNRAS.523.5315P | 420 | X C F | 7 | 33 | ~ | Broad-emission-line dominated hydrogen-rich luminous supernovae. | PESSI P.J., ANDERSON J.P., FOLATELLI G., et al. | ||
2023MNRAS.524..767D | 93 | C | 1 | 21 | ~ | Fast and not-so-furious: Case study of the fast and faint Type IIb SN 2021bxu. | DESAI D.D., ASHALL C., SHAPPEE B.J., et al. | ||
2023A&A...675A..33D | 252 | D | X | 6 | 20 | ~ | The morphing of decay powered to interaction powered Type II supernova ejecta at nebular times. | DESSART L., GUTIERREZ C.P., KUNCARAYAKTI H., et al. | |
2023ApJ...954L..12T | 140 | X | 3 | 17 | ~ | Far-ultraviolet to Near-infrared Observations of SN 2023ixf: A High-energy Explosion Engulfed in Complex Circumstellar Material. | TEJA R.S., SINGH A., BASU J., et al. | ||
2020RNAAS...4..243T | 17 | D | 1 | 263 | ~ | Mid-Infrared Detections of SNe II with NEOWISE. | THEVENOT M. | ||
2023ApJ...954L..42J | 93 | X | 2 | 16 | ~ | SN 2023ixf in Messier 101: Photo-ionization of Dense, Close-in Circumstellar Material in a Nearby Type II Supernova. | JACOBSON-GALAN W.V., DESSART L., MARGUTTI R., et al. | ||
2023ApJ...956L...5B | 448 | A | X C | 9 | 11 | ~ | Early Spectroscopy and Dense Circumstellar Medium Interaction in SN 2023ixf. | BOSTROEM K.A., PEARSON J., SHRESTHA M., et al. | |
2023PASJ...75L..27Y | 355 | A | X C | 7 | 8 | ~ | Bright Type II supernova 2023ixf in M 101: A quick analysis of the early-stage spectra and near-infrared light curves. | YAMANAKA M., FUJII M. and NAGAYAMA T. |