An Upper Limit on the Mass of the Circumplanetary Disk for DH Tau b<sup>*</sup>

Wolff, Schuyler; Ménard, F.; Cáceres, C.; Lefèvre, Charlène; Bonnefoy, M.; Cánovas, H.; Maret, S.; Pinte, C.; Schreiber, M. R.; Plas, G. van der

doi:10.3847/1538-3881/aa74cd

Cited by 42 publications

(32 citation statements)

References 53 publications

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“…Compact dust continuum emission is optically thick, rather than optically thin as usually assumed. We note that similar thoughts have been discussed and applied to derive an upper limit on disk size MacGregor et al 2017;Ricci et al 2017;Wolff et al 2017). Here, we further study the brightness and implications of compact optically-thick disks.…”

Section: Compact Optically-thick Disksupporting

confidence: 54%

An Explanation of the Very Low Radio Flux of Young Planet-mass Companions

Eisner

et al. 2017

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We report Atacama Large Millimeter/submillimeter Array (ALMA) 1.3 mm continuum upper limits for 5 planetary-mass companions DH Tau B, CT Cha B, GSC 6214-210 B, 1RXS 1609 B, and GQ Lup B. Our survey, together with other ALMA studies, have yielded null results for disks around young planet-mass companions and placed stringent dust mass upper limits, typically less than 0.1 M ⊕ , when assuming dust continuum is optically thin. Such low-mass gas/dust content can lead to a disk lifetime estimate (from accretion rates) much shorter than the age of the system. To alleviate this timescale discrepancy, we suggest that disks around wide companions might be very compact and optically thick, in order to sustain a few Myr of accretion yet have very weak (sub)millimeter flux so as to still be elusive to ALMA. Our order-of-magnitude estimate shows that compact optically-thick disks might be smaller than 1000 R Jup and only emit ∼µJy of flux in the (sub)millimeter, but their average temperature can be higher than that of circumstellar disks. The high disk temperature could impede satellite formation, but it also suggests that mid-to far-infrared might be more favorable than radio wavelengths to characterize disk properties. Finally, the compact disk size might imply that dynamical encounters between the companion and the star, or any other scatterers in the system, play a role in the formation of planetary-mass companions.

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Section: Compact Optically-thick Disksupporting

confidence: 54%

An Explanation of the Very Low Radio Flux of Young Planet-mass Companions

Eisner

et al. 2017

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“…Paβ emission was not observed in the moderate-resolution spectroscopy of GQ Lup B presented by McElwain et al (2007) and Lavigne et al (2009), which suggests that the emission observed by Seifahrt et al (2007) was variable. Similarly, Wolff et al (2017) also found variable emission for DH Tau B. This suggests that other companions without Paβ emission could be observed during a quiescent state of low accretion.…”

Section: How Common Is Paβ Emission?mentioning

confidence: 72%

The Young Substellar Companion ROXs 12 B: Near-infrared Spectrum, System Architecture, and Spin–Orbit Misalignment^*

Bowler

Kraus

Bryan

et al. 2017

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ROXs 12 (2MASS J16262803-2526477) is a young star hosting a directly imaged companion near the deuteriumburning limit. We present a suite of spectroscopic, imaging, and time-series observations to characterize the physical and environmental properties of this system. Moderate-resolution near-infrared spectroscopy of ROXs12B from Gemini-North/NIFS and Keck/OSIRIS reveals signatures of low surface gravity including weak alkali absorption lines and a triangular H-band pseudocontinuum shape. No signs of Paβ emission are evident. As a population, however, we find that about half (46%±14%) of young (15 Myr) companions with masses 20M Jup possess actively accreting subdisks detected via Paβ line emission, which represents a lower limit on the prevalence of circumplanetary disks in general, as some are expected to be in a quiescent phase of accretion. The bolometric luminosity of the companion and age of the host star (6 2 4 -+ Myr) imply a mass of 17.5±1.5 M Jup for ROXs 12 B based on hot-start evolutionary models. We identify a wide (5100 au) tertiary companion to this system, 2MASS J16262774-2527247, that is heavily accreting and exhibits stochastic variability in its K2 light curve. By combining v sin i * measurements with rotation periods from K2, we constrain the line-of-sight inclinations of ROXs 12 A and 2MASS J16262774-2527247 and find that they are misaligned by 60 11 7  -+ . In addition, the orbital axis of ROXs12B is likely misaligned from the spin axis of its host star, ROXs12A, suggesting that ROXs 12 B formed akin to fragmenting binary stars or in an equatorial disk that was torqued by the wide stellar tertiary.

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“…This observation is in good agreement with models of magnetic coupling between the planet and its circumplanetary disk (Takata & Stevenson 1996;Batygin 2018), which predict that this mechanism should provide an efficient means of angular momentum dissipation. Interestingly, previous studies have found active accretion signatures for DH Tau b, suggesting that it may still possess a cicumplanetary gas disk (Zhou et al 2014;Bonnefoy et al 2014;Wolff et al 2017).…”

Section: Discussionmentioning

confidence: 97%

“…In this model, the disk extracts angular momentum from the planet, while meridional circulation of gas within the Hill sphere recycles this angular-momentum rich gas back into the circumstellar nebula, thereby decreasing the planet's rotation rate. In fact, there is indirect evidence that DH Tau b is actively accreting, as this object has both Hα and Paβ emission lines in its spectrum (Zhou et al 2014;Bonnefoy et al 2014;Wolff et al 2017). This accretion would presumably be mediated via a circumplanetary gas disk, but Wu et al (2017) did not find any evidence for such a disk when they observed this object with ALMA.…”

Section: Angular Momentum Evolutionmentioning

confidence: 98%

A Rotation Rate for the Planetary-mass Companion DH Tau b

Xuan

Bryan

Knutson

et al. 2020

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DH Tau b is a young planetary-mass companion orbiting at a projected separation of 320 AU from its ∼2 Myr old host star DH Tau. With an estimated mass of 8 − 22 M Jup this object straddles the deuterium-burning limit, and might have formed via core or pebble accretion, disk instability, or molecular cloud fragmentation. To shed light on the formation history of DH Tau b, we obtain the first measurement of rotational line broadening for this object using high-resolution (R ∼25,000) near-infrared spectroscopy from Keck/NIRSPEC. We measure a projected rotational velocity (vsini) of 9.6 ± 0.7 km/s, corresponding to a rotation rate that is between 9-15% of DH Tau b's predicted break-up speed. This low rotation rate is in good agreement with scenarios in which magnetic coupling between the companion and its circumplanetary disk during the late stages of accretion reduces angular momentum and regulates spin. We compare the rotation rate of DH Tau b to published values for other planetary-mass objects with masses between 0.3 − 20 M Jup and find no evidence of a correlation between mass and rotation rate in this mass regime. Finally, we search for evidence of individual molecules in DH Tau b's spectrum and find that it is dominated by CO and H 2 O, with no evidence for the presence of CH 4 . This agrees with expectations given DH Tau b's relatively high effective temperature (∼2300 K).

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An Upper Limit on the Mass of the Circumplanetary Disk for DH Tau b^*

Cited by 42 publications

References 53 publications

An Explanation of the Very Low Radio Flux of Young Planet-mass Companions

An Explanation of the Very Low Radio Flux of Young Planet-mass Companions

The Young Substellar Companion ROXs 12 B: Near-infrared Spectrum, System Architecture, and Spin–Orbit Misalignment^*

A Rotation Rate for the Planetary-mass Companion DH Tau b

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An Upper Limit on the Mass of the Circumplanetary Disk for DH Tau b*

Cited by 42 publications

References 53 publications

An Explanation of the Very Low Radio Flux of Young Planet-mass Companions

An Explanation of the Very Low Radio Flux of Young Planet-mass Companions

The Young Substellar Companion ROXs 12 B: Near-infrared Spectrum, System Architecture, and Spin–Orbit Misalignment*

A Rotation Rate for the Planetary-mass Companion DH Tau b

Contact Info

Product

Resources

About

An Upper Limit on the Mass of the Circumplanetary Disk for DH Tau b^*

The Young Substellar Companion ROXs 12 B: Near-infrared Spectrum, System Architecture, and Spin–Orbit Misalignment^*