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Solving grain size inconsistency between ALMA polarization and VLA continuum in the Ophiuchus IRS 48 protoplanetary disk

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 Added by Satoshi Ohashi
 Publication date 2020
  fields Physics
and research's language is English




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The protoplanetary disk around Ophiuchus IRS 48 shows an azimuthally asymmetric dust distribution in (sub-)millimeter observations, which is interpreted as a vortex, where millimeter/centimeter-sized particles are trapped at the location of the continuum peak. In this paper, we present 860 $mu$m ALMA observations of polarized dust emission of this disk. The polarized emission was detected toward a part of the disk. The polarization vectors are parallel to the disk minor axis, and the polarization fraction was derived to be $1-2$%. These characteristics are consistent with models of self-scattering of submillimeter-wave emission, which indicate a maximum grain size of $sim100$ $mu$m. However, this is inconsistent with the previous interpretation of millimeter/centimeter dust particles being trapped by a vortex. To explain both, ALMA polarization and previous ALMA and VLA observations, we suggest that the thermal emission at 860 $mu$m wavelength is optically thick ($tau_{rm abs}sim7.3$) at the dust trap with the maximum observable grain size of $sim100$ $mu$m rather than an optically thin case with $sim$ cm dust grains. We note that we cannot rule out that larger dust grains are accumulated near the midplane if the 860 $mu$m thermal emission is optically thick.



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