Publications
(34.) AMX Systematic errors on optical-SED stellar-mass estimates for galaxies across cosmic time and their impact on cosmology, A. Paulino-Afonso et al., 2022 A&A., 662, 6.
(33.) AMX A Tale of Two Type Ia Supernovae: The Fast-declining Siblings SNe 2015bo and 1997cn, W. Hoogendam et al., 2022 ApJ, 928 103.
(32.) AM24 HARMONI view of the host galaxies of active galactic nuclei around cosmic noon: Resolved stellar morpho-kinematics and the MBH-s* relation, B. Garcí-Lorenzo et al., 2022 A&A.
(31.) AM21 A Virgo Environmental Survey Tracing Ionised Gas Emission (VESTIGE).XII. Ionised gas emission in the inner regions of lenticular galaxies, A. Boselli et al., 2022 A&A.
(30.) AM40 ASASSN-15hy: an under-luminous, red 03fg-like type Ia supernova, J. Lu et al., 2021 ApJ 920:107.
(29.) AM21 An Amusing Look at the Host of the Periodic Nuclear Transient ASASSN-14ko Reveals a Second AGN, M. Tucker et al., 2021 MNRAS 506:6014.
(28.) AM22 MUSE reveals extended circumnuclear outflows in the Seyfert 1 NGC 7469, A. Robleto-Orús et al., 2021 ApJL 906:6.
(27.) AM21 A Virgo Environmental Survey Tracing Ionised Gas Emission (VESTIGE).IX. The effects of ram pressure stripping down to the scale of individual HII regions in the dwarf galaxy IC 3476, A. Boselli et al., 2021 A&A 646:139.
(26.) AMX Supernova 2018cuf: A Type IIP supernova with a slow fall from plateau, Y. Dong et al., 2021 ApJ 906:56.
(25.) AM34 The delay time distribution of supernovae from integral-field spectroscopy of nearby galaxies, A. Castrillo et al., 2021 MNRAS 501:3122.
(24.) AMX Direct Evidence of Two-component Ejecta in Supernova 2016gkg from Nebular Spectroscopy, H. Kuncarayakti et al., 2020 ApJ 902:139.
(23.) AM33 SN 2017ivv: two years of evolution of a transitional Type II supernova, C. Gutiérrez et al., 2020 MNRAS 499:974.
(22.) AMX Carnegie Supernova Project II: The Slowest Rising Type Ia Supernova LSQ14fmg and Clues to the Origin of Super-Chandrasekhar/03fg-like Events, E. Y. Hsiao et al., 2020; ApJ 900 140.
(21.) AMX The Carnegie Supernova Project II. Observations of the luminous red nova AT 2014ej, M. D. Stritzinger et al., 2020 A&A 639:104.
(20.) AM36 Studying the environment of AT 2018cow with MUSE, J. Lyman et al., 2020 MNRAS 495:992.
(19.) AMX Discovery and Rapid Follow-up Observations of the Unusual Type II SN 2018ivc in NGC 1068, A. Bostroem et al., 2020 ApJ 895 31.
(18.) AMX The AMUSING++ Nearby Galaxy Compilation. I. Full Sample Characterization and Galactic-scale Outflow Selection, C. López-Cobá et al., 2020 AJ 159:167.
(17.) AM29 Nebular Spectra of 111 Type Ia Supernovae Disfavor Single Degenerate Progenitors, M. Tucker et al., 2019 MNRAS 493:1044.
(16.) HKX The 50-100 pc scale parent stellar populations of Type II supernovae and limitations of single star evolution models, P. Schady et al., 2019 MNRAS 490:4515.
(15.) AM16 The extraplanar type II supernova ASASSN-14jb in the nearby edge-on galaxy ESO 467-G051, N. Meza et al., 2019 A&A 629:57.
(14.) SV4 Uncertainties in gas kinematics arising from stellar continuum modeling in integral field spectroscopy data: the case of NGC 2906 observed with VLT/MUSE, E. Bellocchi et al., 2019 A&A 625:A839.
(13.) AMX Carnegie Supernova Project-II: Extending the NIR Hubble Diagram for Type Ia Supernovae to z ∼ 0.1, M. M Phillips et al., 2019; PASP 131 014001.
(12.) AM21 A Virgo Environmental Survey Tracing Ionised Gas Emission (VESTIGE).IV. A tail of Ionised Gas in the Merger Remnant NGC 4424, A. Boselli et al., 2018 A&A 620:164.
(11.) AM28 Serendipitous discovery of a strong-lensed galaxy in integral field spectroscopy from MUSE, L. Galbany et al., 2018 MNRAS 479:262.
(10.) DDT The lowest metallicity type II supernova originating from the highest mass red-supergiant progenitor, J. Anderson et al., 2018 Nature Astronomy 2:574.
(9.) HKX Constraints on core-collapse supernova progenitors from explosion site integral field spectroscopy, H. Kuncarayakti et al., 2018 A&A 613:35.
(8.) AM8 Oxygen abundance gradients + central decrement, L. Sánchez-Menguiano et al., 2018 A&A 609:119.
(7.) AM13 Emission line associated with a AGN driven jet in NGC232, C. Cobá et al., 2017 ApJ 850:17.
(6.) HK1 Hot gas around SN~1998bw - the progenitor from its environment, T. Kruehler et al., 2017 A&A 602:85.
(5.) SV3 Evidence of Ongoing Radial Migration in NGC 6754: Azimuthal Variations of the Gas Properties, L. Sánchez-Menguiano et al., 2016 ApJ 830:40.
(4.) AM15 MUSE Reveals a Recent Merger in the Post-starburst Host Galaxy of the TDE ASASSN-14li, Prieto et al, 2016 ApJ 830:32.
(3.) SVX Unresolved versus resolved: calibrating young SSP models with VLT/MUSE observation of NGC 3603, h. Kuncarayakti et al., 2016 A&A 593:A78.
(2.) SV2 Characterizing the environments of supernovae with MUSE, Galbany et al., 2016 MNRAS 455:4087.
(1.) SV1 Census of H II regions in NGC 6754 derived with MUSE: Constraints on the metal mixing scale, Sánchez et al, 2015 A&A 573:105.