早期阶段的原恒星外流(POETS) V. 通过水糖化器发射原恒星风的机制

L. Moscadelli, A. Oliva, A. Sanna, G. Surcis, O. Bayandina
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摘要

了解风和喷流的发射机制仍然是天体物理学的基本挑战之一。早期原恒星流(POETS)调查最近通过对22 GHz水maser的超长基线干涉测量(VLBI)观测,绘制了37个年轻发光恒星(YSO)样本中10--100 au尺度原恒星风的三维速度场。在大多数目标中,三维水 maser 速度的分布可以用磁流体动力学(MHD)盘风(DW)来解释。我们的目标是评估 POETS 勘测中最有希望成为 MHD 盘风候选者的 YSO 中的原恒星风的发射机制。我们对22 GHz水汲水器进行了多波段甚长基线阵列(VLBA)观测,以确定气体沿先前确定的几条风流线流动的三维速度,线性分辨率为sim 1 au。在YSO附近沿($xl 150$ au)和横跨($R 40$ au)喷气轴的小间隔处,水masers追踪了三条单独的DW流线。通过利用水masers的三维运动学信息,我们确定了这些流线的发射半径,精确度为 \ sim 1 au,它们位于 \ 10--50 au的范围内。沿着喷流的距离越远(110 au $ xl 220$ au),流出气体的速度就越快,同时在靠近喷流轴的地方发生准直。在径向扩展的 MHD DW 中的磁离心发射似乎是唯一可行的过程,可以解释风的快速(高达 60 速)和准直(低至 10 速)与发射半径在 10 至 50 au 之间的对应关系。在与喷气轴的较大距离(100µm)上,水蒸气追踪到的是一个缓慢的(le 20)径向扩展的弧形冲击前沿,其运动学特性与磁离心发射不一致。我们的电阻磁流体动力学模拟表明,这种冲击前沿可能是由磁压驱动的。这些结果表明,对 22 千兆赫水 masers 的 VLBI 观测可以可靠地确定原恒星风的发射机制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Protostellar Outflows at the EarliesT Stages (POETS) V. The launching mechanism of protostellar winds via water masers
Understanding the launching mechanism of winds and jets remains one of the fundamental challenges in astrophysics. The Protostellar Outflows at the EarliesT Stages (POETS) survey has recently mapped the 3D velocity field of the protostellar winds in a sample (37) of luminous young stellar objects (YSOs) at scales of 10--100 au via very long baseline interferometry (VLBI) observations of the 22 GHz water masers. In most of the targets, the distribution of the 3D maser velocities can be explained in terms of a magnetohydrodynamic (MHD) disk wind (DW). Our goal is to assess the launching mechanism of the protostellar wind in the YSO the most promising MHD DW candidate from the POETS survey. We have performed multi-epoch Very Long Baseline Array (VLBA) observations of the 22 GHz water masers in to determine the 3D velocities of the gas flowing along several wind streamlines previously identified at a linear resolution of sim 1 au. Near the YSO at small separations along ($xl 150$ au) and across ($R 40$ au) the jet axis, water masers trace three individual DW streamlines. By exploiting the 3D kinematic information of the masers, we determined the launch radii of these streamlines with an accuracy of \ sim 1 au, and they lie in the range of \ 10--50 au. At increasingly greater distances along the jet (110 au $ xl 220$ au), the outflowing gas speeds up while it collimates close to the jet axis. Magneto-centrifugal launching in a radially extended MHD DW appears to be the only viable process to explain the fast (up to 60 and collimated (down to 10 velocities of the wind in correspondence with launch radii ranging between 10 and 50 au. At larger separations from the jet axis ($R 100$ au), the water masers trace a slow (le 20 radially expanding arched shock-front with kinematics inconsistent with magneto-centrifugal launching. Our resistive-magnetohydrodynamical simulations indicate that this shock-front could be driven by magnetic pressure. The results obtained in demonstrate that VLBI observations of the 22 GHz water masers can reliably determine the launching mechanism of protostellar winds.
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