V* GW Lup , the SIMBAD biblio

V* GW Lup , the SIMBAD biblio (143 results) C.D.S. - SIMBAD4 rel 1.8 - 2024.06.04CEST00:05:24

Sort references on where and how often the object is cited
trying to find the most relevant references on this object.
More on score
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
1962CoBos..15....0T 44 5 On faint H-alpha emission stars in Lupus and Scorpius. THE P.-S.
1966PhDT.........3W viz 13       D               1 2755 122 A study of H-alpha emission objects in the Southern Milky Way. WRAY J.D.
1972ApJ...174..401H 334 403 Second catalog of emission-line stars of the Orion population. HERBIG G.H. and RAO N.K.
1976ApJS...30..491H 14       D               1 1947 250 Observations of southern emission-line stars. HENIZE K.G.
1977ApJS...35..161S 174 248 A survey of southern dark clouds for Herbig-Haro objects and H alf emission stars. SCHWARTZ R.D.
1977IBVS.1248....1K 1048 15 62nd name-list of variable stars. KUKARKIN B.V., KHOLOPOV P.N., FEDOROVICH V.P., et al.
1978AJ.....83..785S 42 16 UBVR photometry of H-alpha emission stars in southern dark clouds. SCHWARTZ R.D. and NOAH P.
1979A&AS...36...57B 54 43 UBV photometry of T Tauri stars and related objects. BASTIAN U. and MUNDT R.
1980A&AS...39..245M 74 29 UBV photometry of young emission-line objects. MUNDT R. and BASTIAN U.
1988LicOB1111....1H viz 742 ~ Third catalog of emission-line stars of the Orion population. HERBIG G.H. and BELL K.R.
1989PASP..101..816H 9 24 Newborn stars and stellar winds in Barnard 228. HEYER M.H. and GRAHAM J.A.
1990ApJS...74..575W 429 96 A catalog of pre-main-sequence emission-line stars with IRAS source associations. WEINTRAUB D.A.
1992ApJS...78..239W viz 732 125 A catalog of co-added IRAS fluxes or Orion population stars. WEAVER W.B. and JONES G.
1994AJ....108.1071H 78 178 The stellar population of the Lupus clouds. HUGHES J., HARTIGAN P., KRAUTTER J., et al.
1994IAUCo.151..203G 70 ~ Flares in T Tauri stars. GAHM G.F.
1996PASJ...48..489T 62 63 13CO (J=1-0) observations of the Lupus molecular clouds. TACHIHARA K., DOBASHI K., MIZUNO A., et al.
1997A&A...324.1036N 34 42 A 1.3mm dust continuum survey of Hα selected T Tauri stars in Lupus. NUERNBERGER D., CHINI R. and ZINNECKER H.
1997A&AS..123..329K viz 382 114 New "weak-line"-T Tauri stars in Lupus. KRAUTTER J., WICHMANN R., SCHMITT J.H.M.M., et al.
1997ApJ...478..295C 265 66 Comparison of star formation in five nearby molecular clouds. CHEN H., GRENFELL T.G., MYERS P.C., et al.
1997ApJ...481..378G 71 208 The multiplicity of pre-main-sequence stars in southern star-forming regions. GHEZ A.M., McCARTHY D.W., PATIENCE J.L., et al.
2003A&A...404..913S viz 1239 88 Formation scenarios for the young stellar associations between galactic longitudes l=280°-360°. SARTORI M.J., LEPINE J.R.D. and DIAS W.S.
2003A&A...410..269M 99 66 The short period multiplicity among T Tauri stars. MELO C.H.F.
2003ApJS..147..305V viz 15       D               273 51 An IUE atlas of Pre-Main-Sequence stars. III. Co-added final archive spectra from the long-wavelength cameras. VALENTI J.A., FALLON A.A. and JOHNS-KRULL C.M.
2005A&A...438..769D viz 1380 87 Pre-main sequence star Proper Motion Catalogue. DUCOURANT C., TEIXEIRA R., PERIE J.-P., et al.
2006ApJ...639..275K 1 81 215 c2d Spitzer IRS spectra of disks around T Tauri stars. I. Silicate emission and grain growth. KESSLER-SILACCI J., AUGEREAU J.-C., DULLEMOND C.P., et al.
2006A&A...459..545G 1         O           50 142 C2D Spitzer-IRS spectra of disks around T Tauri stars. II. PAH emission features. GEERS V.C., AUGEREAU J.-C., PONTOPPIDAN K.M., et al.
2007A&A...461..983V         O           33 13 Searching for gas-rich disks around T Tauri stars in Lupus. VAN KEMPEN T.A., VAN DISHOECK E.F., BRINCH C., et al.
2007A&A...462..211L 1         O           30 73 Investigating grain growth in disks around southern T Tauri stars at millimetre wavelengths. LOMMEN D., WRIGHT C.M., MADDISON S.T., et al.
2007A&A...467.1147G 90       D       C       2 142 92 Pre-main sequence spectroscopic binaries suitable for VLTI observations. GUENTHER E.W., ESPOSITO M., MUNDT R., et al.
2007ApJ...665..492L 87 115 c2d Spitzer IRS spectra of disks around T Tauri stars. III. [Ne II], [Fe I], and H2Gas-Phase lines. LAHUIS F., VAN DISHOECK E.F., BLAKE G.A., et al.
2007A&A...476..279G 15       D               2 39 72 Spatially extended polycyclic aromatic hydrocarbons in circumstellar disks around T Tauri and Herbig Ae stars. GEERS V.C., VAN DISHOECK E.F., VISSER R., et al.
2008A&A...489..633P 18       D               1 25 151 Probing dust grain evolution in IM Lupi's circumstellar disc. Multi-wavelength observations and modelling of the dust disc. PINTE C., PADGETT D.L., MENARD F., et al.
2009A&A...507..327O 15       D   O           2 124 89 C2D Spitzer-IRS spectra of disks around T Tauri stars. IV. Crystalline silicates. OLOFSSON J., AUGEREAU J.-C., VAN DISHOECK E.F., et al.
2010A&A...515A..77L 53       D     X         2 95 38 Grain growth across protoplanetary discs: 10 µm silicate feature versus millimetre slope. LOMMEN D.J.P., VAN DISHOECK E.F., WRIGHT C.M., et al.
2010ApJ...720..887P 15       D               2 86 171 A Spitzer survey of mid-infrared molecular emission from protoplanetary disks. I. Detection rates. PONTOPPIDAN K.M., SALYK C., BLAKE G.A., et al.
2010A&A...519A.113G 15       D               7 103 59 On the origin of [NeII] 12.81 µm emission from pre-main sequence stars: disks, jets, and accretion. GUEDEL M., LAHUIS F., BRIGGS K.R., et al.
2010A&A...520A..39O 92       D   O   C       3 70 31 C2D Spitzer-IRS spectra of disks around T Tauri stars. V. Spectral decomposition. OLOFSSON J., AUGEREAU J.-C., VAN DISHOECK E.F., et al.
2011ApJ...731..130S 15       D               3 75 127 A Spitzer survey of mid-infrared molecular emission from protoplanetary disks. II. Correlations and local thermal equilibrium models. SALYK C., PONTOPPIDAN K.M., BLAKE G.A., et al.
2011A&A...529A.108L viz 15       D               1 190 14 A proper motion study of the Lupus clouds using virtual observatory tools. LOPEZ MARTI B., JIMENEZ-ESTEBAN F. and SOLANO E.
2013A&A...549A..15F 16       D               1 102 28 Young stars in ε Chamaleontis and their disks: disk evolution in sparse associations. FANG M., VAN BOEKEL R., BOUWMAN J., et al.
2014A&A...561A...2A viz 18       D               16 65 270 X-shooter spectroscopy of young stellar objects. IV. Accretion in low-mass stars and substellar objects in Lupus. ALCALA J.M., NATTA A., MANARA C.F., et al.
2014ApJ...786...97H viz 16       D               1 329 295 An optical spectroscopic study of T Tauri stars. I. Photospheric properties. HERCZEG G.J. and HILLENBRAND L.A.
2014A&A...569A...5N 94       D       C       6 47 69 X-shooter spectroscopy of young stellar objects. V. Slow winds in T Tauri stars. NATTA A., TESTI L., ALCALA J.M., et al.
2014A&A...572A..62A 94       D       C       4 158 21 POISSON project. III. Investigating the evolution of the mass accretion rate. ANTONIUCCI S., GARCIA LOPEZ R., NISINI B., et al.
2016AJ....151..146C viz 16       D               1 787 1 A systematic search for the spectra with features of crystalline silicates in the Spitzer IRS enhanced products. CHEN R., LUO A., LIU J., et al.
2016A&A...591L...3M 18       D               1 64 137 Evidence for a correlation between mass accretion rates onto young stars and the mass of their protoplanetary disks. MANARA C.F., ROSOTTI G., TESTI L., et al.
2016ApJ...828...46A viz 20       D               1 111 483 ALMA survey of Lupus protoplanetary disks. I. Dust and gas masses. ANSDELL M., WILLIAMS J.P., VAN DER MAREL N., et al.
2016ApJ...831..125P viz 16       D               1 427 330 A steeper than linear disk mass-stellar mass scaling relation. PASCUCCI I., TESTI L., HERCZEG G.J., et al.
2017ApJ...837..163R 17       D               1 32 63 Protoplanetary disks as (possibly) viscous disks. RAFIKOV R.R.
2017A&A...599A.105A 244           X C       5 38 4 X-shooter spectroscopy of young stellar objects. VI. H I line decrements. ANTONIUCCI S., NISINI B., GIANNINI T., et al.
2017A&A...599A.113M 42           X         1 93 155 Lupus disks with faint CO isotopologues: low gas/dust or high carbon depletion? MIOTELLO A., VAN DISHOECK E.F., WILLIAMS J.P., et al.
2017A&A...600A..20A viz 99       D       C       3 135 270 X-shooter spectroscopy of young stellar objects in Lupus. Accretion properties of class II and transitional objects. ALCALA J.M., MANARA C.F., NATTA A., et al.
2017A&A...601A..36B 246           X C       5 12 33 CO2 infrared emission as a diagnostic of planet-forming regions of disks. BOSMAN A.D., BRUDERER S. and VAN DISHOECK E.F.
2017A&A...602A..33F viz 97       D       C       4 115 64 X-shooter spectroscopy of young stellar objects in Lupus. Atmospheric parameters, membership, and activity diagnostics. FRASCA A., BIAZZO K., ALCALA J.M., et al.
2017MNRAS.467..812M 1113       D     X C F     26 55 4 The JCMT Gould Belt Survey: a first look at SCUBA-2 observations of the Lupus I molecular cloud. MOWAT C., HATCHELL J., RUMBLE D., et al.
2017ApJ...847...31M viz 16       D               1 174 26 Constraints from dust mass and mass accretion rate measurements on angular momentum transport in protoplanetary disks. MULDERS G.D., PASCUCCI I., MANARA C.F., et al.
2017A&A...605A..66B 16       D   O           1 97 6 X-shooter spectroscopy of young stellar objects in Lupus. Lithium, iron, and barium elemental abundances. BIAZZO K., FRASCA A., ALCALA J.M., et al.
2017A&A...606A..88T 993       D     X C       24 54 113 Physical properties of dusty protoplanetary disks in Lupus: evidence for viscous evolution? TAZZARI M., TESTI L., NATTA A., et al.
2018A&A...609A..87N 16       D     X         1 143 59 Connection between jets, winds and accretion in T Tauri stars. The X-shooter view. NISINI B., ANTONIUCCI S., ALCALA J.M., et al.
2018A&A...609A..93C 49           X         1 6 53 CN rings in full protoplanetary disks around young stars as probes of disk structure. CAZZOLETTI P., VAN DISHOECK E.F., VISSER R., et al.
2018ApJ...859...21A viz 18       D               4 107 270 ALMA survey of Lupus protoplanetary disks. II. Gas disk radii. ANSDELL M., WILLIAMS J.P., TRAPMAN L., et al.
2018A&A...616A.100Y 16       D     X         1 49 4 Stellar masses and disk properties of Lupus young stellar objects traced by velocity-aligned stacked ALMA 13CO and C18O spectra. YEN H.-W., KOCH P.M., MANARA C.F., et al.
2018ApJ...865..157A 16       D               6 118 104 Scaling relations associated with millimeter continuum sizes in protoplanetary disks. ANDREWS S.M., TERRELL M., TRIPATHI A., et al.
2018A&A...618L...3M 17       D               2 131 147 Why do protoplanetary disks appear not massive enough to form the known exoplanet population? MANARA C.F., MORBIDELLI A. and GUILLOT T.
2018ApJ...867..151D viz 16       D               1 389 80 Distances and kinematics of Gould Belt star-forming regions with Gaia DR2 results. DZIB S.A., LOINARD L., ORTIZ-LEON G.N., et al.
2018ApJ...868...28F 16       D               3 74 61 A new look at T Tauri star forbidden lines: MHD-driven winds from the inner disk. FANG M., PASCUCCI I., EDWARDS S., et al.
2018A&A...619A..52B viz 16       D               1 48 8 A catalogue of dense cores and young stellar objects in the Lupus complex based on Herschel Gould Belt Survey observations. BENEDETTINI M., PEZZUTO S., SCHISANO E., et al.
2018ApJ...869L..41A viz 38       D               5 30 685 The Disk Substructures at High Angular Resolution Project (DSHARP). I. Motivation, sample, calibration, and overview. ANDREWS S.M., HUANG J., PEREZ L.M., et al.
2018ApJ...869L..42H viz 475       D     X C       11 49 314 The Disk Substructures at High Angular Resolution Project (DSHARP). II. Characteristics of annular substructures. HUANG J., ANDREWS S.M., DULLEMOND C.P., et al.
2018ApJ...869L..46D 509       D     X C       11 6 244 The disk substructures at high angular resolution project (DSHARP). VI. Dust trapping in thin-ringed protoplanetary disks. DULLEMOND C.P., BIRNSTIEL T., HUANG J., et al.
2018ApJ...869L..47Z 274       D S   X C       5 25 298 The Disk Substructures at High Angular Resolution Project (DSHARP). VII. The planet-disk interactions interpretation. ZHANG S., ZHU Z., HUANG J., et al.
2018A&A...620A..94G 182       D     X         5 75 88 Evolution of protoplanetary disks from their taxonomy in scattered light: spirals, rings, cavities, and shadows. GARUFI A., BENISTY M., PINILLA P., et al.
2018A&A...620A.172Z viz 16       D               1 127608 99 3D mapping of young stars in the solar neighbourhood with Gaia DR2. ZARI E., HASHEMI H., BROWN A.G.A., et al.
2019ApJ...870...76B 17       D               2 83 75 Kinematic links and the coevolution of MHD winds, jets, and inner disks from a high-resolution optical [OI] survey. BANZATTI A., PASCUCCI I., EDWARDS S., et al.
2019A&A...623A.150V 2240   K A S   X C       52 106 34 The ALMA Lupus protoplanetary disk survey: evidence for compact gas disks and molecular rings from CN. VAN TERWISGA S.E., VAN DISHOECK E.F., CAZZOLETTI P., et al.
2019MNRAS.486..453L 20       D               1 35 112 The newborn planet population emerging from ring-like structures in discs. LODATO G., DIPIERRO G., RAGUSA E., et al.
2019MNRAS.488L..12N viz 17       D               1 24 ~ ALMA observations require slower Core Accretion runaway growth. NAYAKSHIN S., DIPIERRO G. and SZULAGYI J.
2019A&A...629A.108A 42           X         1 92 38 HST spectra reveal accretion in MY Lupi. ALCALA J.M., MANARA C.F., FRANCE K., et al.
2019ApJ...884L...5S 6 9 55 The DSHARP rings: evidence of ongoing planetesimal formation? STAMMLER S.M., DRAZKOWSKA J., BIRNSTIEL T., et al.
2019A&A...631L...2M 172 49 Constraining disk evolution prescriptions of planet population synthesis models with observed disk masses and accretion rates. MANARA C.F., MORDASINI C., TESTI L., et al.
2019A&A...631A..69M viz 529     A     X C       12 23 57 Bright C2H emission in protoplanetary discs in Lupus: high volatile C/O > 1 ratios. MIOTELLO A., FACCHINI S., VAN DISHOECK E.F., et al.
2020ApJ...890L...9P 47     A D               3 25 117 Nine localized deviations from Keplerian rotation in the DSHARP circumstellar disks: kinematic evidence for protoplanets carving the gaps. PINTE C., PRICE D.J., MENARD F., et al.
2020MNRAS.492..210V 43           X         1 15 ~ Self-induced dust traps around snow lines in protoplanetary discs. VERICEL A. and GONZALEZ J.-F.
2020A&A...635A.105P 17       D               1 78 47 Hints on the origins of particle traps in protoplanetary disks given by the Mdust - M relation. PINILLA P., PASCUCCI I. and MARINO S.
2020ApJ...895..109F 48           X         1 21 106 Measuring turbulent motion in planet-forming disks with ALMA: a detection around DM Tau and nondetections around MWC 480 and V4046 Sgr. FLAHERTY K., HUGHES A.M., SIMON J.B., et al.
2020ApJ...895..126H viz 17       D               3 177 62 The evolution of dust disk sizes from a homogeneous analysis of 1-10 Myr old stars. HENDLER N., PASCUCCI I., PINILLA P., et al.
2020A&A...638A..38T 315       D     X         8 33 ~ Constraining the radial drift of millimeter-sized grains in the protoplanetary disks in Lupus. TRAPMAN L., ANSDELL M., HOGERHEIJDE M.R., et al.
2020ApJ...899...55A viz 17       D               1 165 8 Search for alignment of disk orientations in nearby star-forming regions: Lupus, Taurus, Upper Scorpius, ρ Ophiuchi, and Orion. AIZAWA M., SUTO Y., OYA Y., et al.
2020A&A...640A...5T 18       D               2 38 47 Observed sizes of planet-forming disks trace viscous spreading. TRAPMAN L., ROSOTTI G., BOSMAN A.D., et al.
2020MNRAS.498.2845S 87           X         2 15 31 A dusty origin for the correlation between protoplanetary disc accretion rates and dust masses. SELLEK A.D., BOOTH R.A. and CLARKE C.J.
2020AJ....160..186L viz 17       D               1 235 15 A Gaia survey for young stars associated with the Lupus clouds. LUHMAN K.L.
2020ApJ...903..124B 17       D               2 67 38 Hints for icy pebble migration feeding an oxygen-rich chemistry in the inner planet-forming region of disks. BANZATTI A., PASCUCCI I., BOSMAN A.D., et al.
2020A&A...644A.119P 85           X         2 18 ~ ALMA chemical survey of disk-outflow sources in Taurus (ALMA-DOT). III. The interplay between gas and dust in the protoplanetary disk of DG Tau. PODIO L., GARUFI A., CODELLA C., et al.
2021ApJ...907...80O 17       D               1 23 17 Ring formation by coagulation of dust aggregates in the early phase of disk evolution around a protostar. OHASHI S., KOBAYASHI H., NAKATANI R., et al.
2021ApJ...908...46B 17       D               4 76 16 Dynamical stellar masses of pre-main-sequence stars in Lupus and Taurus obtained with ALMA surveys in comparison with stellar evolutionary models. BRAUN T.A.M., YEN H.-W., KOCH P.M., et al.
2021AJ....161..146J 366       D     X         9 27 18 A search for companions via direct imaging in the DSHARP planet-forming disks. JORQUERA S., PEREZ L.M., CHAUVIN G., et al.
2021MNRAS.502.5325R 19       D               1 9 22 Constraining protoplanetary disc accretion and young planets using ALMA kinematic observations. RABAGO I. and ZHU Z.
2021A&A...649A..19S 670       D     X C F     14 53 39 Measuring the ratio of the gas and dust emission radii of protoplanetary disks in the Lupus star-forming region. SANCHIS E., TESTI L., NATTA A., et al.
2021AJ....162...28V viz 17       D               1 661 47 A stellar mass dependence of structured disks: a possible link with exoplanet demographics. VAN DER MAREL N. and MULDERS G.D.
2021ApJ...916...51A 454       D     X C       10 15 19 Limits on millimeter continuum emission from circumplanetary material in the DSHARP disks. ANDREWS S.M., ELDER W., ZHANG S., et al.
2021MNRAS.506.2804T 17       D               5 51 33 Multiwavelength continuum sizes of protoplanetary discs: scaling relations and implications for grain growth and radial drift. TAZZARI M., CLARKE C.J., TESTI L., et al.
2021MNRAS.506.5117T 409       D     X C       9 54 25 The first ALMA survey of protoplanetary discs at 3 mm: demographics of grain growth in the Lupus region. TAZZARI M., TESTI L., NATTA A., et al.
2021A&A...653L...9V 104       D         F     3 29 16 If you like C/O variations, you should have put a ring on it. VAN DER MAREL N., BOSMAN A.D., KRIJT S., et al.
2021MNRAS.507..818T 88           X         2 21 32 On the secular evolution of the ratio between gas and dust radii in protoplanetary discs. TOCI C., ROSOTTI G., LODATO G., et al.
2021MNRAS.507.5523T 44           X         1 4 ~ Axisymmetric simulations of the convective overstability in protoplanetary discs. TEED R.J. and LATTER H.N.
2021ApJ...921...72M viz 17       D               1 277 37 Bridging the gap between protoplanetary and debris disks: separate evolution of millimeter and micrometer-sized Dust. MICHEL A., VAN DER MAREL N. and MATTHEWS B.C.
2021ApJS..257...11B 45           X         1 12 22 Molecules with ALMA at Planet-forming Scales (MAPS). XI. CN and HCN as tracers of photochemistry in disks. BERGNER J.B., OBERG K.I., GUZMAN V.V., et al.
2022MNRAS.509.2780J 915       D     X   F     20 20 24 A super-resolution analysis of the DSHARP survey: substructure is common in the inner 30 au. JENNINGS J., BOOTH R.A., TAZZARI M., et al.
2021ApJ...923..165W 104       D     X         3 40 4 Architecture of planetary systems predicted from protoplanetary disks observed with ALMA. I. Mass of the possible planets embedded in the dust gap. WANG S., KANAGAWA K.D. and SUTO Y.
2022MNRAS.510.1657C 421       D     X C F     8 21 2 Testing planet formation from the ultraviolet to the millimetre. CHOKSI N. and CHIANG E.
2022MNRAS.510.4473Z 225           X C F     3 5 6 PGNets: planet mass prediction using convolutional neural networks for radio continuum observations of protoplanetary discs. ZHANG S., ZHU Z. and KANG M.
2022A&A...658A.137G 690       D     X C       15 81 23 A SPHERE survey of self-shadowed planet-forming disks. GARUFI A., DOMINIK C., GINSKI C., et al.
2022MNRAS.511.2453P 152       D     X         4 817 ~ Taxonomy of protoplanetary discs observed with ALMA. PARKER R., WARD-THOMPSON D. and KIRK J.
2022ApJ...930..111D 45           X         1 14 2 Clumpy Accretion in Pre-main-sequence Stars as a Source of Perturbations in Circumstellar Disks. DEMIDOVA T.V. and GRININ V.P.
2022ApJ...931....6L 242       D     X         6 59 23 Gas Disk Sizes from CO Line Observations: A Test of Angular Momentum Evolution. LONG F., ANDREWS S.M., ROSOTTI G., et al.
2022ApJ...932..114L 582     A D     X C       13 23 16 CO Line Emission Surfaces and Vertical Structure in Midinclination Protoplanetary Disks. LAW C.J., CRYSTIAN S., TEAGUE R., et al.
2022A&A...663A..98T viz 18       D               1 511 23 The protoplanetary disk population in the ρ-Ophiuchi region L1688 and the time evolution of Class II YSOs. TESTI L., NATTA A., MANARA C.F., et al.
2022ApJS..263...14C viz 18       D               1 434 2 A Population of Dipper Stars from the Transiting Exoplanet Survey Satellite Mission. CAPISTRANT B.K., SOARES-FURTADO M., VANDERBURG A., et al.
2022A&A...666A.188E 18       D               2 122 4 The He I λ10830 Å line as a probe of winds and accretion in young stars in Lupus and Upper Scorpius. ERKAL J., MANARA C.F., SCHNEIDER P.C., et al.
2022A&A...667A.114J 18       D               1 114 1 SPHERE adaptive optics performance for faint targets. JONES M.I., MILLI J., BLANCHARD I., et al.
2022ApJ...940L..43S 896     A D     X C       20 15 4 Testing Velocity Kinks as a Planet Detection Method: Do Velocity Kinks in Surface Gas Emission Trace Planetary Spiral Wakes in the Midplane Continuum? SPEEDIE J. and DONG R.
2023ApJ...942....4X 19       D               1 74 5 Measuring the Dust Masses of Protoplanetary Disks in Lupus with ALMA: Evidence That Disks Can Be Optically Thick at 3 mm. XIN Z., ESPAILLAT C.C., RILINGER A.M., et al.
2023A&A...670A.126F 280     A D     X         7 15 ~ Forbidden emission lines in protostellar outflows and jets with MUSE. FLORES-RIVERA L., FLOCK M., KURTOVIC N.T., et al.
2023ApJ...944..185A 112       D       C       5 65 2 Lyα Scattering Models Trace Accretion and Outflow Kinematics in T Tauri Systems. ARULANANTHAM N., GRONKE M., FIORELLINO E., et al.
2023ApJ...945..112F 19       D               1 201 1 A High-resolution Optical Survey of Upper Sco: Evidence for Coevolution of Accretion and Disk Winds. FANG M., PASCUCCI I., EDWARDS S., et al.
2023A&A...671A..46M 625       D S   X         13 77 ~ New members of the Lupus I cloud based on Gaia astrometry Physical and accretion properties from X-shooter spectra. MAJIDI F.Z., ALCALA J.M., FRASCA A., et al.
2023ApJ...947L...6G 1801     A     X C       38 7 6 MINDS. The Detection of 13CO2 with JWST-MIRI Indicates Abundant CO2 in a Protoplanetary Disk. GRANT S.L., VAN DISHOECK E.F., TABONE B., et al.
2023ApJ...948...57P 19       D               2 115 ~ An SMA Survey of Chemistry in Disks Around Herbig AeBe Stars. PEGUES J., OBERG K.I., QI C., et al.
2023ApJ...948...60L 93             C       1 31 4 Mapping Protoplanetary Disk Vertical Structure with CO Isotopologue Line Emission. LAW C.J., TEAGUE R., OBERG K.I., et al.
2023A&A...672L..15Z 93             C       1 14 1 Testing protoplanetary disc evolution with CO fluxes A proof of concept in Lupus and Upper Sco. ZAGARIA F., FACCHINI S., MIOTELLO A., et al.
2023A&A...673A..80C 112       D         F     2 56 1 Empirical determination of the lithium 6707.856 Å wavelength in young stars. CAMPBELL-WHITE J., MANARA C.F., SICILIA-AGUILAR A., et al.
2023ApJ...952..108Z 93             C       1 50 ~ Substructures in Compact Disks of the Taurus Star-forming Region. ZHANG S., KALSCHEUR M., LONG F., et al.
2023MNRAS.524.3184P 998       D S   X C F     19 22 ~ Constraining turbulence in protoplanetary discs using the gap contrast: an application to the DSHARP sample. PIZZATI E., ROSOTTI G.P. and TABONE B.
2023ApJ...953..183P 392       D     X         9 37 ~ Large Myr-old Disks Are Not Severely Depleted of Gas-phase CO or Carbon. PASCUCCI I., SKINNER B.N., DENG D., et al.
2023AJ....166...67F 19       D               2 76 ~ The Radial Distribution and Excitation of H2 around Young Stars in the HST-ULLYSES Survey. FRANCE K., ARULANANTHAM N., MALONEY E., et al.
2023ApJ...954...41T 19       D               1 68 ~ How Large Is a Disk-What Do Protoplanetary Disk Gas Sizes Really Mean? TRAPMAN L., ROSOTTI G., ZHANG K., et al.
2023MNRAS.525.2806C 19       D               1 19 ~ The maximum accretion rate of a protoplanet: how fast can runaway be? CHOKSI N., CHIANG E., FUNG J., et al.
2023AJ....166..184M 47           X         1 32 ~ Finding Substructures in Protostellar Disks in Ophiuchus. MICHEL A., SADAVOY S.I., SHEEHAN P.D., et al.
2023A&A...678A..33J 47           X         1 10 ~ Chemical footprints of giant planet formation Role of planet accretion in shaping the C/O ratio of protoplanetary disks. JIANG H., WANG Y., ORMEL C.W., et al.
2023ApJ...958L..30R 187           X C       3 15 ~ XUE: Molecular Inventory in the Inner Region of an Extremely Irradiated Protoplanetary Disk. RAMIREZ-TANNUS M.C., BIK A., CUIJPERS L., et al.
2023A&A...679A.117G 280           X         6 5 ~ MINDS Abundant water and varying C/O across the disk of Sz 98 as seen by JWST/MIRI. GASMAN D., VAN DISHOECK E.F., GRANT S.L., et al.
2023ApJ...959L..25X 93           X         2 10 ~ Water-rich Disks around Late M Stars Unveiled: Exploring the Remarkable Case of Sz 114. XIE C., PASCUCCI I., LONG F., et al.
2024A&A...682A..91V 850           X C       16 7 ~ Mid-infrared spectra of T Tauri disks: Modeling the effects of a small inner cavity on CO2 and H2O emission. VLASBLOM M., VAN DISHOECK E.F., TABONE B., et al.

goto View the references in ADSLimited to 100