PTF 09axc , the SIMBAD biblio

PTF 09axc , the SIMBAD biblio (36 results) C.D.S. - SIMBAD4 rel 1.7 - 2021.03.02CET06:47:26


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Title First 3 Authors
2021ApJ...907...77Z 50           X         1 20 ~ Measuring black hole masses from tidal disruption events and testing the MBH* relation. ZHOU Z.Q., LIU F.K., KOMOSSA S., et al.
2021ApJ...908....4V 20       D               1 35 ~ Seventeen tidal disruption events from the first half of ZTF survey observations: entering a new era of population studies. VAN VELZEN S., GEZARI S., HAMMERSTEIN E., et al.
2020ApJ...889..166J 2659     A D S   X C       56 26 ~ Implications from late-time X-ray detections of optically selected tidal disruption events: state changes, unification, and detection rates. JONKER P.G., STONE N.C., GENEROZOV A., et al.
2020ApJ...904...73R 345       D     X C       7 24 ~ Measuring stellar and black hole masses of tidal disruption events. RYU T., KROLIK J. and PIRAN T.
2020ApJ...905L...5U 19       D               1 22 ~ Application of the wind-driven model to a sample of tidal disruption events. UNO K. and MAEDA K.
2020MNRAS.498.2167K 93           X         2 22 ~ AT 2017gbl: a dust obscured TDE candidate in a luminous infrared galaxy. KOOL E.C., REYNOLDS T.M., MATTILA S., et al.
2020MNRAS.499..482N 140           X         3 14 ~ An outflow powers the optical rise of the nearby, fast-evolving tidal disruption event AT2019qiz. NICHOLL M., WEVERS T., OATES S.R., et al.
2019ApJ...872..198V 18       D               1 13 ~ The first tidal disruption flare in ZTF: from photometric selection to multi-wavelength characterization. VAN VELZEN S., GEZARI S., CENKO S.B., et al.
2019ApJ...878...82V 45           X         1 19 ~ Late-time UV observations of tidal disruption flares reveal unobscured, compact accretion disks. VAN VELZEN S., STONE N.C., METZGER B.D., et al.
2019MNRAS.487.4136W 63       D     X         2 39 ~ Black hole masses of tidal disruption event host galaxies II. WEVERS T., STONE N.C., VAN VELZEN S., et al.
2018ApJ...852...72V viz 105       D     X         3 18 19 On the mass and luminosity functions of tidal disruption flares: rate suppression due to black hole event horizons. VAN VELZEN S.
2018ApJ...853...39G 192       D     X C       4 41 9 A dependence of the tidal disruption event rate on global stellar surface mass density and stellar velocity dispersion. GRAUR O., FRENCH K.D., ZAHID H.J., et al.
2018ApJ...865..128L 44           X         1 19 1 On the missing energy puzzle of tidal disruption events. LU W. and KUMAR P.
2018ApJS..238...15H 148       D     X C       3 33 6 Sifting for sapphires: systematic selection of tidal disruption events in iPTF. HUNG T., GEZARI S., CENKO S.B., et al.
2018MNRAS.474.3307S 17       D               1 17 7 Spectral features of tidal disruption candidates and alternative origins for such transient flares. SAXTON C.J., PERETS H.B. and BASKIN A.
2018MNRAS.480.5060S 87             C       1 14 ~ The delay time distribution of tidal disruption flares. STONE N.C., GENEROZOV A., VASILIEV E., et al.
2017ApJ...835..176F 359       D     X C       8 9 15 The post-starburst evolution of tidal disruption event host galaxies. FRENCH K.D., ARCAVI I. and ZABLUDOFF A.
2017ApJ...838..149A 783       D     X         19 99 40 New physical insights about tidal disruption events from a comprehensive observational inventory At X-ray wavelengths. AUCHETTL K., GUILLOCHON J. and RAMIREZ-RUIZ E.
2017ApJ...850...22L 17       D               1 23 11 Tidal disruption event host galaxies in the context of the local galaxy population. LAW-SMITH J., RAMIREZ-RUIZ E., ELLISON S.L., et al.
2017MNRAS.464.2481G 187       D       C F     8 22 15 The influence of circumnuclear environment on the radio emission from TDE jets. GENEROZOV A., MIMICA P., METZGER B.D., et al.
2017MNRAS.465L.114W viz 43           X         1 13 11 OGLE16aaa - a signature of a hungry supermassive black hole. WYRZYKOWSKI L., ZIELINSKI M., KOSTRZEWA-RUTKOWSKA Z., et al.
2017MNRAS.471.1694W 18       D               3 16 20 Black hole masses of tidal disruption event host galaxies. WEVERS T., VAN VELZEN S., JONKER P.G., et al.
2016A&A...596A..67R 42           X         1 60 9 SN 2012aa: A transient between Type Ibc core-collapse and superluminous supernovae. ROY R., SOLLERMAN J., SILVERMAN J.M., et al.
2016ApJ...818L..21F 103       D     X         3 15 53 Tidal disruption events prefer unusual host galaxies. FRENCH K.D., ARCAVI I. and ZABLUDOFF A.
2016ApJ...829...19V 394       D     X C       9 12 16 Discovery of transient infrared emission from dust heated by stellar tidal disruption flares. VAN VELZEN S., MENDEZ A.J., KROLIK J.H., et al.
2016MNRAS.455..859S 251           X C F     4 165 110 Rates of stellar tidal disruption as probes of the supermassive black hole mass function. STONE N.C. and METZGER B.D.
2016MNRAS.455.2918H viz 48           X         1 17 111 Six months of multiwavelength follow-up of the tidal disruption candidate ASASSN-14li and implied TDE rates from ASAS-SN. HOLOIEN T.W.-S., KOCHANEK C.S., PRIETO J.L., et al.
2016MNRAS.458..127K 43           X         1 11 19 Abundance anomalies in tidal disruption events. KOCHANEK C.S.
2016MNRAS.461..371K 88             C       1 9 41 Tidal disruption event demographics. KOCHANEK C.S.
2016Sci...351...62V 2 24 59 A radio jet from the optical and X-ray bright stellar tidal disruption flare ASASSN-14li. VAN VELZEN S., ANDERSON G.E., STONE N.C., et al.
2015ApJ...806..164P 25       D               1 7 67 'Disk formation versus disk accretion–What powers tidal disruption events? PIRAN T., SVIRSKI G., KROLIK J., et al.
2014ApJ...789...23K viz 16       D               1 344 36 The host galaxies of fast-ejecta core-collapse supernovae. KELLY P.L., FILIPPENKO A.V., MODJAZ M., et al.
2014ApJ...793...38A viz 1716     A D S   X C       41 15 162 A continuum of H- to He-rich tidal disruption candidates with a preference for E+A galaxies. ARCAVI I., GAL-YAM A., SULLIVAN M., et al.
2014MNRAS.445.3263H 45           X         1 26 111 ASASSN-14ae: a tidal disruption event at 200 Mpc. HOLOIEN T.W.-S., PRIETO J.L., BERSIER D., et al.
2013ApJ...773...12S 16       D               1 73 32 Probing the low-redshift star formation rate as a function of metallicity through the local environments of type II supernovae. STOLL R., PRIETO J.L., STANEK K.Z., et al.
2010ApJ...721..777A 16       D               1 82 129 Core-collapse supernovae from the Palomar transient factory: indications for a different population in dwarf galaxies. ARCAVI I., GAL-YAM A., KASLIWAL M.M., et al.

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2021.03.02-06:47:26

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