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| SN 2009N , the SIMBAD biblio (94 results) | C.D.S. - SIMBAD4 rel 1.8 - 2024.04.16CEST23:39:55 |
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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 |
|---|---|---|---|---|---|---|---|---|---|
| 2009CBET.1670....1N | 41 | T | O X | 1 | 6 | Supernova 2009N in NGC 4487. | NAKANO S., KADOTA K. and BUZZI L. | ||
| 2009CBET.1671....1C | 40 | T | O X | 1 | 4 | Supernova 2009N in NGC 4487. | CHALLIS P. and BERLIND P. | ||
| 2009CBET.1671....2W | 39 | T | O X | 1 | 3 | Supernova 2009N in NGC 4487. | WELLS W. | ||
| 2009CBET.1673....1C | 38 | T | O X | 1 | 1 | Supernova 2009N in NGC 4487. | CHALLIS P. and BERLIND P. | ||
| 2009CBET.1673....3W | 38 | T | O X | 1 | 0 | Supernova 2009N in NGC 4487. | WELLS W. | ||
2012A&A...538A.120L 
|
15 | D | 1 | 5598 | 37 | A unified supernova catalogue. | LENNARZ D., ALTMANN D. and WIEBUSCH C. | ||
| 2012MNRAS.420.3451M | 868 | D | X C F | 21 | 13 | 34 | Constraining the physical properties of type II-plateau supernovae using nebular phase spectra. | MAGUIRE K., JERKSTRAND A., SMARTT S.J., et al. | |
| 2009ATel.1914....1I | 76 | T | 1 | 2 | 2 |
Swift observations of SN 2009N in NGC 4487. |
IMMLER S. and BROWN P.J. | ||
| 2009ATel.1915....1S | 76 | T | 1 | 6 | 3 |
Radio non-detections of type IIP supernovae 2008ij (NGC 6643), 2009H (NGC 1084), and 2009N (4487). |
STOCKDALE C.J., WEILER K.W., IMMLER S., et al. | ||
| 2009ATel.1925....1S | 76 | T | 1 | 4 | 0 |
Radio non-detections of type IIP supernovae 2009H (NGC 1084) and 2009N (NGC 4487). |
STOCKDALE C.J., HEIM M.S., WEILER K.W., et al. | ||
| 2012ApJ...756..111M | 15 | D | 1 | 100 | 114 | Core-collapse supernovae missed by optical surveys. | MATTILA S., DAHLEN T., EFSTATHIOU A., et al. | ||
| 2013MNRAS.428.1927C | 16 | D | 2 | 330 | 52 | On the association between core-collapse supernovae and HII regions. | CROWTHER P.A. | ||
|
2013MNRAS.436..774E
|
16 | D | 1 | 250 | 249 | The death of massive stars - II. Observational constraints on the progenitors of type Ibc supernovae. | ELDRIDGE J.J., FRASER M., SMARTT S.J., et al. | ||
| 2014MNRAS.438..368T | 3699 | T A | D | X C F | 92 | 18 | 46 |
SN 2009N: linking normal and subluminous Type II-P SNe. |
TAKATS K., PUMO M.L., ELIAS-ROSA N., et al. |
| 2014MNRAS.439.2873S | 253 | D | X F | 6 | 40 | 125 | Low luminosity Type II supernovae - II. Pointing towards moderate mass precursors. | SPIRO S., PASTORELLO A., PUMO M.L., et al. | |
| 2014ApJ...786...67A | 16 | D | 4 | 234 | 250 | Characterizing the V-band light-curves of hydrogen-rich type II supernovae. | ANDERSON J.P., GONZALEZ-GAITAN S., HAMUY M., et al. | ||
| 2014ApJ...786L..15G | 16 | D | 1 | 110 | 45 | Hα spectral diversity of type II supernovae: correlations with photometric properties. | GUTIERREZ C.P., ANDERSON J.P., HAMUY M., et al. | ||
| 2014ApJ...787..157P | 16 | D | 1 | 51 | 35 | Bolometric and UV light curves of core-collapse supernovae. | PRITCHARD T.A., ROMING P.W.A., BROWN P.J., et al. | ||
| 2014MNRAS.440.1856D | 79 | F | 1 | 22 | 30 | Type II Plateau supernovae as metallicity probes of the Universe. | DESSART L., GUTIERREZ C.P., HAMUY M., et al. | ||
| 2014AstL...40..291C | 10 | 7 | Does the energy of type IIP supernovae depend on the stellar mass? | CHIGAI N.N. and UTROBIN V.P. | |||||
|
2014ApJ...795..142G
|
16 | D | 1 | 448 | 7 | Defining photometric peculiar type Ia supernovae. | GONZALEZ-GAITAN S., HSIAO E.Y., PIGNATA G., et al. | ||
| 2014AJ....148..107R | 173 | D | X | 5 | 104 | 44 | Photospheric magnitude diagrams for Type II supernovae: a promising tool to compute distances. | RODRIGUEZ O., CLOCCHIATTI A. and HAMUY M. | |
| 2014A&A...571A..77N | 315 | S X C | 6 | 10 | 15 | A semianalytical light curve model and its application to Type IIP supernovae. | NAGY A.P., ORDASI A., VINKO J., et al. | ||
| 2014ApJ...797....5Z | 810 | A | X C | 20 | 19 | 14 | Optical and ultraviolet observations of a low-velocity type II plateau supernova 2013am in M65. | ZHANG J., WANG X., MAZZALI P.A., et al. | |
|
2015ApJ...799..215P
|
373 | D | X C | 9 | 53 | 38 | A global model of the light curves and expansion velocities of Type II-Plateau supernovae. | PEJCHA O. and PRIETO J.L. | |
| 2015A&A...577A..44O | 79 | C | 4 | 28 | 12 | Multiwavelength analysis of three supernovae associated with gamma-ray bursts observed by GROND. | OLIVARES E.F., GREINER J., SCHADY P., et al. | ||
| 2015ApJ...806..160B | 96 | D | C | 2 | 23 | 61 | SN 2013ej: a Type IIL supernova with weak signs of interaction. | BOSE S., SUTARIA F., KUMAR B., et al. | |
| 2015MNRAS.450.2373B | 40 | X | 1 | 19 | 37 | SN 2013ab: a normal Type IIP supernova in NGC 5669. | BOSE S., VALENTI S., MISRA K., et al. | ||
|
2015MNRAS.450.3137T
|
1470 | A | D | X C F | 36 | 27 | 32 | SN 2009ib: a Type II-P supernova with an unusually long plateau. | TAKATS K., PIGNATA G., PUMO M.L., et al. |
| 2015MNRAS.451.2212G | 42 | X | 1 | 25 | 107 | The rise-time of Type II supernovae. | GONZALEZ-GAITAN S., TOMINAGA N., MOLINA J., et al. | ||
| 2015ApJ...815..121D | 16 | D | 1 | 57 | 20 | A Hubble diagram from Type II supernovae based solely on photometry: the photometric color method. | DE JAEGER T., GONZALEZ-GAITAN S., ANDERSON J.P., et al. | ||
|
2016ApJ...820...33R
|
16 | D | 1 | 70 | 56 | Type II supernova energetics and comparison of light curves to shock-cooling models. | RUBIN A., GAL-YAM A., DE CIA A., et al. | ||
| 2016ApJ...823..127N | 17 | D | 1 | 25 | 27 | The importance of 56Ni in shaping the light curves of type II supernovae. | NAKAR E., POZNANSKI D. and KATZ B. | ||
| 2016A&A...589A..53N | 177 | D | X | 5 | 18 | 16 | A two-component model for fitting light curves of core-collapse supernovae. | NAGY A.P. and VINKO J. | |
|
2016A&A...589A.110A
|
16 | D | 2 | 217 | 17 | Type II supernovae as probes of environment metallicity: observations of host H II regions. | ANDERSON J.P., GUTIERREZ C.P., DESSART L., et al. | ||
|
2016MNRAS.459.3939V
|
178 | D | C F | 6 | 210 | 225 | The diversity of Type II supernova versus the similarity in their progenitors. | VALENTI S., HOWELL D.A., STRITZINGER M.D., et al. | |
| 2015ATel.8399....1L | 40 | X | 1 | 5 | 2 | PESSTO spectroscopic classification of optical transients. | LE GUILLOU L., LE BRETON R., CHEN T.-W., et al. | ||
|
2017ApJ...835..166D
|
16 | D | 1 | 89 | 18 | A Type II supernova Hubble diagram from the CSP-I, SDSS-II, and SNLS surveys. | DE JAEGER T., GONZALEZ-GAITAN S., HAMUY M., et al. | ||
| 2017MNRAS.464.3013P | 301 | D | X F | 7 | 30 | 11 | Radiation-hydrodynamical modelling of underluminous Type II plateau supernovae. | PUMO M.L., ZAMPIERI L., SPIRO S., et al. | |
| 2017ApJ...850...89G | 57 | D | X | 2 | 252 | 84 | Type II supernova spectral diversity. I. Observations, sample characterization, and spectral line evolution. | GUTIERREZ C.P., ANDERSON J.P., HAMUY M., et al. | |
| 2017ApJ...850...90G | 16 | D | 3 | 124 | 51 | Type II supernova spectral diversity. II. Spectroscopic and photometric correlations. | GUTIERREZ C.P., ANDERSON J.P., HAMUY M., et al. | ||
|
2017ApJS..233....6H
|
16 | D | 12 | 122 | 13 | Type II supernova light curves and spectra from the CfA. | HICKEN M., FRIEDMAN A.S., BLONDIN S., et al. | ||
| 2018MNRAS.473..513F | 510 | D | X C F | 11 | 29 | 10 | The evolution of temperature and bolometric luminosity in Type II supernovae. | FARAN T., NAKAR E. and POZNANSKI D. | |
| 2018ApJS..234...34P | 243 | C | 1 | 7 | 1127 | Modules for Experiments in Stellar Astrophysics (MESA): convective boundaries, element diffusion, and massive star explosions. | PAXTON B., SCHWAB J., BAUER E.B., et al. | ||
| 2018MNRAS.475.1937T | 412 | X C F | 8 | 27 | 11 | SNe 2013K and 2013am: observed and physical properties of two slow, normal Type IIP events. | TOMASELLA L., CAPPELLARO E., PUMO M.L., et al. | ||
| 2018MNRAS.475.3959H | 58 | D | X | 2 | 26 | 18 | SN 2016X: a type II-P supernova with a signature of shock breakout from explosion of a massive red supergiant. | HUANG F., WANG X.-F., HOSSEINZADEH G., et al. | |
| 2018ApJ...858...15M | 20 | D | 2 | 23 | 111 | Measuring the progenitor masses and dense circumstellar material of Type II supernovae. | MOROZOVA V., PIRO A.L. and VALENTI S. | ||
| 2018MNRAS.476.4592D | 140 | D | X F | 3 | 75 | 11 | Observed Type II supernova colours from the Carnegie Supernova Project-I. | DE JAEGER T., ANDERSON J.P., GALBANY L., et al. | |
| 2018A&A...613A..35K | 16 | D | 3 | 171 | 55 | Constraints on core-collapse supernova progenitors from explosion site integral field spectroscopy. | KUNCARAYAKTI H., ANDERSON J.P., GALBANY L., et al. | ||
| 2018NatAs...2..574A | 1 | 12 | 16 | The lowest-metallicity type II supernova from the highest-mass red supergiant progenitor. | ANDERSON J.P., DESSART L., GUTIERREZ C.P., et al. | ||||
| 2018MNRAS.473.3863L | 510 | K | D | S X F | 11 | 83 | 13 | Progenitors of low-luminosity Type II-Plateau supernovae. | LISAKOV S.M., DESSART L., HILLIER D.J., et al. |
| 2018MNRAS.479.2421D | 181 | D | X F | 4 | 48 | 10 | SN 2015ba: a Type IIP supernova with a long plateau. | DASTIDAR R., MISRA K., HOSSEINZADEH G., et al. | |
| 2018MNRAS.479.3232G | 16 | D | 3 | 254 | 15 | Type II supernovae in low-luminosity host galaxies. | GUTIERREZ C.P., ANDERSON J.P., SULLIVAN M., et al. | ||
| 2018MNRAS.480.2475S | 16 | D | 1 | 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. | ||
| 2019ApJ...870L..16S | 17 | D | 1 | 39 | ~ | Bright Type IIP supernovae in (low-metallicity) galaxies. | SCOTT S., NICHOLL M., BLANCHARD P., 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. | |
| 2019PASP..131f8002B | 42 | X | 1 | 12 | 2 | Presto-Color: a photometric Survey cadence for explosive physics and fast transients. | BIANCO F.B., DROUT M.R., GRAHAM M.L., et al. | ||
| 2019ApJ...877...92O | 84 | C | 1 | 10 | ~ | Constraining massive star activities in the final years through properties of supernovae and their progenitors. | OUCHI R. and MAEDA K. | ||
| 2019ApJ...880...59R | 42 | X | 1 | 19 | ~ | Excavating the explosion and progenitor properties of Type IIP supernovae via modeling of their optical light curves. | RICKS W. and DWARKADAS V.V. | ||
|
2019MNRAS.488.4239P
|
17 | D | 2 | 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. | ||
| 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. | ||
| 2019ApJ...887....4D | 17 | D | 1 | 73 | ~ | Carnegie Supernova Project-II: near-infrared spectroscopic diversity of Type II supernovae. | DAVIS S., HSIAO E.Y., ASHALL C., et al. | ||
| 2019MNRAS.490.1605D | 184 | D | 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 | 226 | D | X F | 5 | 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. | |
| 2019MNRAS.490.4515S | 811 | D | X C F | 18 | 24 | ~ | The 50-100 pc scale parent stellar populations of Type II supernovae and limitations of single star evolution models. | SCHADY P., ELDRIDGE J.J., ANDERSON J., et al. | |
| 2020ApJ...890..177K | 43 | X | 1 | 19 | ~ | A new method to classify Type IIP/IIL supernovae based on their spectra. | KOU S., CHEN X. and LIU X. | ||
| 2020MNRAS.494.5576P | 85 | X | 2 | 24 | ~ | The mystery of photometric twins DES17X1boj and DES16E2bjy. | PURSIAINEN M., GUTIERREZ C.P., WISEMAN P., et al. | ||
| 2020MNRAS.496.3725J | 17 | D | 1 | 18 | ~ | A low-luminosity core-collapse supernova very similar to SN 2005cs. | JAGER Z., VINKO J., BIRO B.I., et al. | ||
| 2020MNRAS.496.4517S | 60 | D | X | 2 | 46 | 22 | The γ-ray deposition histories of core-collapse supernovae. | SHARON A. and KUSHNIR D. | |
| 2020MNRAS.497..361M | 570 | D | X F | 13 | 44 | ~ | The low-luminosity Type II SN 2016aqf: a well-monitored spectral evolution of the Ni/Fe abundance ratio. | MULLER-BRAVO T.E., GUTIERREZ C.P., SULLIVAN M., et al. | |
|
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. | ||
| 2021MNRAS.501.1059R | 392 | X C F | 7 | 24 | ~ | Low-luminosity Type II supernovae - III. SN 2018hwm, a faint event with an unusually long plateau. | REGUITTI A., PUMO M.L., MAZZALI P.A., et al. | ||
| 2021A&A...645A...6Z | 104 | D | F | 6 | 34 | 29 | Effect of binary evolution on the inferred initial and final core masses of hydrogen-rich, Type II supernova progenitors. | ZAPARTAS E., DE MINK S.E., JUSTHAM S., et al. | |
| 2021ApJ...908...75B | 17 | D | 1 | 556 | 32 | The radio luminosity-risetime function of core-collapse supernovae. | BIETENHOLZ M.F., BARTEL N., ARGO M., et al. | ||
| 2021MNRAS.501.3122C | 17 | D | 1 | 116 | ~ | The delay time distribution of supernovae from integral-field spectroscopy of nearby galaxies. | CASTRILLO A., ASCASIBAR Y., GALBANY L., et al. | ||
| 2021MNRAS.504.1009D | 87 | F | 1 | 38 | ~ | The optical properties of three Type II supernovae: 2014cx, 2014cy, and 2015cz. | DASTIDAR R., MISRA K., SINGH M., et al. | ||
| 2021MNRAS.505.1742R | 453 | D | X C F | 9 | 264 | 9 | The iron yield of normal Type II supernovae. | RODRIGUEZ O., MEZA N., PINEDA-GARCIA J., et al. | |
|
2021A&A...655A..90Y
|
104 | D | C | 2 | 53 | 13 | A low-energy explosion yields the underluminous Type IIP SN 2020cxd. | YANG S., SOLLERMAN J., STROTJOHANN N.L., 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. | ||
| 2022MNRAS.512.2777T | 90 | F | 2 | 31 | 15 | Progenitor and close-in circumstellar medium of type II supernova 2020fqv from high-cadence photometry and ultra-rapid UV spectroscopy. | TINYANONT S., RIDDEN-HARPER R., FOLEY R.J., et al. | ||
| 2022A&A...660A..40M | 197 | D | X C | 4 | 147 | 6 | Type II supernovae from the Carnegie Supernova Project-I. I. Bolometric light curves of 74 SNe II using uBgVriYJH photometry. | MARTINEZ L., BERSTEN M.C., ANDERSON J.P., et al. | |
| 2022A&A...660A..41M | 197 | D | X C | 4 | 86 | 16 | Type II supernovae from the Carnegie Supernova Project-I. II. Physical parameter distributions from hydrodynamical modelling. | MARTINEZ L., BERSTEN M.C., ANDERSON J.P., et al. | |
| 2022MNRAS.513.4556Z | 63 | D | X | 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. | ||
| 2022MNRAS.513.4983V | 45 | X | 1 | 24 | 9 | Low luminosity Type II supernovae - IV. SN 2020cxd and SN 2021aai, at the edges of the sub-luminous supernovae class. | VALERIN G., PUMO M.L., PASTORELLO A., 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. | ||
| 2022ApJ...933..194P | 90 | C | 1 | 9 | ~ | Type IIP Supernova IV. Shock Breakout from Progenitor Stars Modeled with Convective Overshoot and Mass Loss. | PALANI BALAJI H., RAY A., WAGLE G.A., et al. | ||
| 2022MNRAS.515..897R | 376 | D | X C F | 7 | 122 | 8 | Luminosity distribution of Type II supernova progenitors. | RODRIGUEZ O. | |
| 2022ApJ...939..105B | 134 | S X | 2 | 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. | ||
| 2023ApJ...942...38M | 485 | D | X C | 10 | 19 | ~ | Locating Type II-P Supernovae Using the Expanding Photosphere Method. I. Comparing Distances from Different Line Velocities. | MITCHELL R.C., DIDIER B., GANESH S., et al. | |
| 2023ApJ...945..107P | 140 | X C | 2 | 39 | 5 | Circumstellar Medium Interaction in SN 2018lab, A Low-luminosity Type IIP Supernova Observed with TESS. | PEARSON J., HOSSEINZADEH G., SAND D.J., et al. | ||
| 2023MNRAS.518.5741S | 252 | D | X C | 5 | 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.524.2186V | 93 | C | 1 | 13 | ~ | Identifying the SN 2022acko progenitor with JWST. | VAN DYK S.D., BOSTROEM K.A., ZHENG W., et al. |
