<i>K</i>-band GRAVITY/VLTI interferometry of “extreme” Herbig Be stars

Marcos-Arenal, P.; Mendigutía, I.; Koumpia, E.; Oudmaijer, R. D.; Vioque, M.; Guzmán-Díaz, J.; Wichittanakom, C.; Wit, W. J. de; Montesinos, B.; Ilee, John D.

doi:10.1051/0004-6361/202140724

Cited by 10 publications

(4 citation statements)

References 88 publications

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“…The dashed line shows the expected dust sublimation radius for a sublimation temperature of 1500 K as R subl = L /4πσT 4 subl , following previous work (Monnier & Millan-Gabet 2002;Dullemond & Monnier 2010;Lazareff et al 2017), which can partly provide an explanation but is unable to explain the data across the whole range in luminosities (see e.g. discussion in Marcos-Arenal et al 2021). As an estimate of R subl , we therefore take and outlier-resistant mean in six logarithmic bins, which is shown with an orange solid line in Figure 21, and interpolate that over the measured luminosities in our sample to obtain an estimate of R subl in each disk.…”

Section: Peculiarities In Individual Spectramentioning

confidence: 84%

Scanning disk rings and winds in CO at 0.01-10 au: a high-resolution $M$-band spectroscopy survey with IRTF-iSHELL

Banzatti,

Abernathy,

Brittain

et al. 2022

Preprint

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We present an overview and first results from a M-band spectroscopic survey of planet-forming disks performed with iSHELL on IRTF, using two slits that provide resolving power R ≈ 60,000-92,000 (5-3.3 km/s). iSHELL provides a nearly complete coverage at 4.52-5.24 µm in one shot, covering > 50 lines from the R and P branches of 12 CO and 13 CO for each of multiple vibrational levels, and providing unprecedented information on the excitation of multiple emission and absorption components. Some of the most notable new findings of this survey are: 1) the detection of two CO Keplerian rings at < 2 au (in HD 259431), 2) the detection of H 2 O ro-vibrational lines at 5 µm (in AS 205 N), and 3) the common kinematic variability of CO lines over timescales of 1-14 years. By homogeneously analyzing this survey together with a previous VLT-CRIRES survey of cooler stars, we discuss a unified view of CO spectra where emission and absorption components scan the disk surface across radii from a dust-free region within dust sublimation out to ≈ 10 au. We classify two fundamental types of CO line shapes interpreted as emission from Keplerian rings (double-peak lines) and a disk surface plus a low-velocity part of a wind (triangular lines), where CO excitation reflects different emitting regions (and their gas-to-dust ratio) rather than just the irradiation spectrum. A disk+wind interpretation for the triangular lines naturally explains several properties observed in CO spectra, including the line blue-shifts, line shapes that turn into narrow absorption at high inclinations, and the frequency of disk winds as a function of stellar type.

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Section: Peculiarities In Individual Spectramentioning

confidence: 84%

Scanning disk rings and winds in CO at 0.01-10 au: a high-resolution $M$-band spectroscopy survey with IRTF-iSHELL

Banzatti,

Abernathy,

Brittain

et al. 2022

Preprint

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“…In addition, there are alternative explanations to the change of trend in hydrogen line luminosity properties, apart from a change in accretion mode (see Mendigutía et al 2015;Marcos-Arenal et al 2021). For example, outflowing material could be dominating the line emission (caused by, e.g., disk photoevaporation, Guzmán-Díaz et al 2021).…”

Section: Interpretation Of the Change In Accretion Gradientmentioning

confidence: 99%

Identification and Spectroscopic Characterization of 128 New Herbig Stars*

Vioque

Oudmaijer

Wichittanakom

et al. 2022

ApJ

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We present optical spectroscopy observations of 145 high-mass pre-main-sequence candidates from the catalog of Vioque et al. 2020 From these, we provide evidence for the Herbig nature of 128 sources. This increases the number of known objects of the class by ∼50%. We determine the stellar parameters of these sources using the spectra and Gaia EDR3 data. The new sources are well distributed in mass and age, with 23 sources between 4 and 8 M ⊙ and 32 sources above 8 M ⊙. Accretion rates are inferred from Hα and Hβ luminosities for 104 of the new Herbigs. These accretion rates, combined with previous similar estimates, allow us to analyze the accretion properties of Herbig stars using the largest sample ever considered. We provide further support to the existence of a break in accretion properties at ∼3–4 M ⊙, which was already reported for the previously known Herbig stars. We re-estimate the potential break in accretion properties to be at 3.87 − 0.96 + 0.38 M ⊙. As observed for the previously known Herbig stars, the sample of new Herbig stars independently suggests intense inner-disk photoevaporation for sources with masses above ∼7 M ⊙. These observations provide robust observational support to the accuracy of the Vioque et al. 2020 catalog of Herbig candidates.

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“…Between 1.5 < M < 8 M e , YSOs are categorized into the Herbig Ae/Be group (e.g., Vioque et al 2018), at the latest stages of pre-main-sequence evolution, and their cooler predecessors the intermediate-mass T Tauris (IMTTs; e.g., Valegård et al 2021). At M > 8 to 10 M e , YSOs are generally referred to as massive YSOs (MYSOs; e.g., Koumpia et al 2021;Marcos-Arenal et al 2021). In this work, we use the term "intermediateand highmass" when referring to any YSO with M > 1.5 M e and optically bright enough to be detected by Gaia (as opposed to the T Tauri regime containing optically bright low-mass YSOs).…”

Section: Sample Completeness and Biasesmentioning

confidence: 99%

Clustering Properties of Intermediate and High-mass Young Stellar Objects*

Vioque,

Cavieres,

González

et al. 2023

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We have selected 337 intermediate- and high-mass young stellar objects (YSOs; 1.5–20 M ⊙) well-characterized with spectroscopy. By means of the clustering algorithm HDBSCAN, we study their clustering and association properties in the Gaia DR3 catalog as a function of stellar mass. We find that the lower-mass YSOs (1.5–4 M ⊙) have clustering rates of 55%–60% in Gaia astrometric space, a percentage similar to that found in the T Tauri regime. However, intermediate-mass YSOs in the range 4–10 M ⊙ show a decreasing clustering rate with stellar mass, down to 27%. We find tentative evidence suggesting that massive YSOs (>10 M ⊙) often (yet not always) appear clustered. We put forward the idea that most massive YSOs form via a mechanism that demands many low-mass stars around them. However, intermediate-mass YSOs form in a classical core-collapse T Tauri way, yet they do not appear often in the clusters around massive YSOs. We also find that intermediate- and high-mass YSOs become less clustered with decreasing disk emission and accretion rate. This points toward an evolution with time. For those sources that appear clustered, no major correlation is found between their stellar properties and the cluster sizes, number of cluster members, cluster densities, or distance to cluster centers. In doing this analysis, we report the identification of 55 new clusters. We tabulated all of the derived cluster parameters for the considered intermediate- and high-mass YSOs.

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K-band GRAVITY/VLTI interferometry of “extreme” Herbig Be stars

Cited by 10 publications

References 88 publications

Scanning disk rings and winds in CO at 0.01-10 au: a high-resolution $M$-band spectroscopy survey with IRTF-iSHELL

Scanning disk rings and winds in CO at 0.01-10 au: a high-resolution $M$-band spectroscopy survey with IRTF-iSHELL

Identification and Spectroscopic Characterization of 128 New Herbig Stars*

Clustering Properties of Intermediate and High-mass Young Stellar Objects*

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