Dust entrainment in photoevaporative winds: Densities and imaging
Abstract
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. We constrain the dust densities in a typical XEUV-driven outflow, and determine whether these winds can be observed at μm-wavelengths in scattered and polarised light. For an XEUV-driven outflow around a M* = 0.7\,M T-Tauri star with LX = 2 · 1030\,erg/s, we find a dust mass-loss rate Mdust 4.1 · 10-11\,M / yr for an optimistic estimate of dust densities in the wind (compared to Mgas ≈ 3.7 · 10-8\,M / yr). The synthesised scattered-light images suggest a distinct chimney structure emerging at intensities I/I < 10-4.5 (10-3.5) at λobs = 1.6 (0.4) μm, while the features in the polarised-light images are even fainter. Observations synthesised from our model do not exhibit clear features for SPHERE IRDIS, but show a faint wind signature for JWST NIRCam under optimal conditions. In conclusion, unambiguous detections of photoevaporative XEUV winds launched from primordial disks are at least challenging with current instrumentation; this provides a possible explanation as to why disk winds are not routinely detected in scattered or polarised light.
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