The dispersal of protoplanetary discs – I. A new generation of X-ray photoevaporation models

Picogna, Giovanni; Ercolano, Barbara; Owen, James E.; Weber, Michael L.

doi:10.1093/mnras/stz1166

Cited by 134 publications

(250 citation statements)

References 68 publications

(152 reference statements)

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“…As a consequence, the accretion rate dramatically decreases (the so-called UV switch) and the inner disc is accreted on its own (shorter) timescale, producing a transition disc in ∼ 10 5 yr, in agreement with observational results (Ercolano et al 2011a). In recent years, attention has been paid also to other heating radiation fields such as the far ultra-violet (FUV) (Gorti & Hollenbach 2008) and soft X-rays (Alexander et al 2005;Ercolano et al 2008;Owen et al 2010;Picogna et al 2019), leading to the development of multiple photoevaporation models (see Alexander et al 2014 for a review) that differ in the mass-loss rates, the shape of the mass-loss profile and the link between the properties of the wind and the ones of the central star (such as the stellar UV or X-ray flux). In general, however, the more recent models tend to predict significantly higher mass-loss rates compared to the original EUV model.…”

Section: Introductionsupporting

confidence: 77%

Effects of photoevaporation on protoplanetary disc ‘isochrones’

Somigliana

Toci

Lodato

et al. 2019

Monthly Notices of the Royal Astronomical Society

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Protoplanetary discs are the site of star and planet formation, and their evolution and consequent dispersal deeply affect the formation of planetary systems. In the standard scenario they evolve on timescales ∼ Myr due to the viscous transport of angular momentum. The analytical self-similar solution for their evolution predicts also specific disc isochrones in the accretion rate -disc mass plane. However, photoevaporation by radiation emitted by the central star is likely to dominate the gas disc dispersal of the innermost region, introducing another (shorter) timescale for this process. In this paper, we include the effect of internal (X and EUV) photoevaporation on the disc evolution, finding numerical solutions for a population of protoplanetary discs. Our models naturally reproduce the expected quick dispersal of the inner region of discs when their accretion rates match the rate of photoevaporative mass loss, in line with previous studies. We find that photoevaporation preferentially removes the lightest discs in the sample. The net result is that, counter-intuitively, photoevaporation increases the average disc mass in the sample, by dispersing the lightest discs. At the same time, photoevaporation also reduces the mass accretion rate by cutting the supply of material from the outer to the inner disc. In a purely viscous framework, this would be interpreted as the result of a longer viscous evolution, leading to an overestimate of the disc age. Our results thus show that photoevaporation is a necessary ingredient to include when interpreting observations of large disc samples with measured mass accretion rates and disc masses. Photoevaporation leaves a characteristic imprint on the shape of the isochrone. Accurate data in the accretion rate -disc mass plane in the low disc mass region therefore give clues on the typical photoevaporation rate.

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Section: Introductionsupporting

confidence: 77%

Effects of photoevaporation on protoplanetary disc ‘isochrones’

Somigliana

Toci

Lodato

et al. 2019

Monthly Notices of the Royal Astronomical Society

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“…11 With increasing R, max(a 0 ) slowly decreases out to R max 140 AU, where it quickly drops to max(a 0 ) = 0. This coincides with the maximum radius at which XEUV photoevaporation is effective for the gas component of the disk; Picogna et al (2019) show that the surface mass-loss rate (Σ gas ) drops to negligible values at R ≈ 140 AU. So both gas and dust residing at the disk surface at R 140 AU are very unlikely to be thermally unbound from there.…”

Section: Maximum Entrained Grain Sizesupporting

confidence: 64%

“…Note that omitting disk gravity should not have a strong effect on the strength of the flaring seen here, see Appendix A.15 Picogna et al (2019) provide a more in-depth explanation of the differences between their model and that ofOwen et al (2011b).Article number, page 9 of 18 A&A proofs: manuscript no. Draft…”

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confidence: 73%

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Dust entrainment in photoevaporative winds: The impact of X-rays

Franz

Picogna

Ercolano

et al. 2020

A&A

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Context. X-ray-and EUV-(XEUV-) driven photoevaporative winds acting on protoplanetary disks around young T-Tauri stars may crucially impact disk evolution, affecting both gas and dust distributions. Aims. We investigate the dust entrainment in XEUV-driven photoevaporative winds and compare our results to existing MHD and EUV-only models. Methods. We used a 2D hydrodynamical gas model of a protoplanetary disk irradiated by both X-ray and EUV spectra from a central T-Tauri star to trace the motion of passive Lagrangian dust grains of various sizes. The trajectories were modelled starting at the disk surface in order to investigate dust entrainment in the wind. Results. For an X-ray luminosity of LX = 2·10 30 erg/s emitted by a M * = 0.7 M star, corresponding to a wind mass-loss rate ofṀw 2.6 · 10 −8 M /yr, we find dust entrainment for sizes a0 11 µm (9 µm) from the inner 25 AU (120 AU). This is an enhancement over dust entrainment in less vigorous EUV-driven winds withṀw 10 −10 M /yr. Our numerical model also shows deviations of dust grain trajectories from the gas streamlines even for µm-sized particles. In addition, we find a correlation between the size of the entrained grains and the maximum height they reach in the outflow.Conclusions. X-ray-driven photoevaporative winds are expected to be dust-rich if small grains are present in the disk atmosphere.Key words. protoplanetary disks -stars: T-Tauri -dust entrainment -photoevaporative winds: XEUV -methods: numerical -silicate grains -young stellar objects -interstellar dust processes 1 The ionization parameter is defined as ξ = L * /(n r 2 ), with L * the stellar luminosity, n the gas density, and r the (spherical) radial distance from the star. 2 '2.5D' meaning a 2D coordinate system (r, ϑ) with 3D velocity information (vr, v ϑ , vϕ).Article number, page 2 of 18 R. Franz et al.: Dust entrainment in photoevaporative winds: The impact of X-rays

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“…By contrast, the effects of the observed stellar XUV flux on the disc are expected to be significant. Models of X-ray photoevaporation show that an X-ray luminosity of L X = 5 × 10 29 erg s −1 produces a wind mass-loss rate ofṀ w ≃ 10 −8 M ⊙ yr −1 Owen & Jackson 2012;Picogna, et al 2019). The mass of gas in the PDS70 disc is not well-constrained, but for standard assumptions (i.e., a gas-to-dust ratio of 100) the disc models used to fit the dust observations imply a total disc mass M d 10 −2 -10 −3 M ⊙ (e.g.…”

Section: Discussionmentioning

confidence: 99%

A Swift view of X-ray and UV radiation in the planet-forming T Tauri system PDS 70

Joyce

Pye

Nichols

et al. 2019

Monthly Notices of the Royal Astronomical Society: Letters

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PDS 70 is a ∼5 Myr old star with a gas and dust disc in which several proto-planets have been discovered. We present the first UV detection of the system along with Xray observations taken with the Neil Gehrels Swift Observatory satellite. PDS 70 has an X-ray flux of 3.4×10 −13 erg cm −2 s −1 in the 0.3-10.0 keV range, and UV flux (U band) of 3.5×10 −13 erg cm −2 s −1 . At the distance of 113.4 pc determined from Gaia DR2 this gives luminosities of 5.2×10 29 erg s −1 and 5.4×10 29 erg s −1 respectively. The X-ray luminosity is consistent with coronal emission from a rapidly rotating star close to the log L X L bol ∼ −3 saturation limit. We find the UV luminosity is much lower than would be expected if the star were still accreting disc material and suggest that the observed UV emission is coronal in origin.

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The dispersal of protoplanetary discs – I. A new generation of X-ray photoevaporation models

Cited by 134 publications

References 68 publications

Effects of photoevaporation on protoplanetary disc ‘isochrones’

Effects of photoevaporation on protoplanetary disc ‘isochrones’

Dust entrainment in photoevaporative winds: The impact of X-rays

A Swift view of X-ray and UV radiation in the planet-forming T Tauri system PDS 70

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