VLTI/AMBER spectro-interferometry of the Herbig Be star MWC 297 with spectral resolution 12 000

TL;DR

This study uses high-resolution infrared spectro-interferometry to resolve the inner regions of the Herbig Be star MWC 297, revealing a compact continuum-emitting disk and an extended, asymmetric Br gamma-emitting disk wind, interpreted through magneto-centrifugal models.

Contribution

First high spectral resolution interferometric study of MWC 297 combining observations with disk-wind modeling to characterize the inner disk and wind structure.

Findings

Continuum-emitting region is ~0.56 AU, much smaller than dust sublimation radius.

Br gamma emission region is more extended (~1.6 AU) and asymmetric.

Disk wind ejection region is at ~0.5 AU with a large half-opening angle of ~80 degrees.

Abstract

Circumstellar disks and outflows play a fundamental role in star formation. Infrared spectro-interferometry allows the inner accretion-ejection region to be resolved. We measured interferometric visibilities, wavelength-differential phases, and closure phases of MWC 297 with a spectral resolution of 12000. To interpret our MWC 297 observations, we employed disk-wind models. The measured continuum visibilities confirm previous results that the continuum-emitting region of MWC 297 is remarkably compact. We derive a continuum ring-fit radius of ~2.2 mas (~0.56 AU at a distance of 250 pc), which is ~5.4 times smaller than the 3 AU dust sublimation radius expected for silicate grains (in the absence of radiation-shielding material). The strongly wavelength-dependent and asymmetric Br gamma-emitting region is more extended (~2.7 times) than the continuum-emitting region. At the center of the Br gamma line, we derive a Gaussian fit radius of ~6.3 mas HWHM (~1.6 AU). To interpret the observations, we employ a magneto-centrifugally driven disk-wind model consisting of an accretion disk, which emits the observed continuum radiation, and a disk wind, which emits the Br gamma line. The calculated wavelength-dependent model intensity distributions and Br gamma line profiles are compared with the observations (i.e., K-band spectrum, visibilities, differential phases, and closure phases). The closest fitting model predicts a continuum-emitting disk with an inner radius of ~0.3 AU and a disk wind ejection region with an inner radius of ~0.5 AU (~17.5 stellar radii). We obtain a disk-wind half-opening angle (the angle between the rotation axis and the innermost streamline of the disk wind) of ~80 degrees, which is larger than in T Tau models, and a disk inclination angle of ~20 degrees (i.e., almost pole-on).