Dynamics of magnetic flux tubes in accretion disks of Herbig Ae/Be stars

IF 0.5 4区 物理与天体物理 Q4 ASTRONOMY & ASTROPHYSICS
Sergey A. Khaibrakhmanov, Alexander E. Dudorov
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Abstract

The dynamics of magnetic flux tubes (MFTs) in the accretion disk of typical Herbig Ae/Be star (HAeBeS) with fossil large-scale magnetic field is modeled taking into account the buoyant and drag forces, radiative heat exchange with the surrounding gas, and the magnetic field of the disk. The structure of the disk is simulated using our magnetohydrodynamic model, taking into account the heating of the surface layers of the disk with the stellar radiation. The simulations show that MFTs periodically rise from the innermost region of the disk with speeds up to 10–12 km s 1 {{\rm{s}}}^{-1} . MFTs experience decaying magnetic oscillations under the action of the external magnetic field near the disk’s surface. The oscillation period increases with distance from the star and initial plasma beta of the MFT, ranging from several hours at r = 0.012 au r=0.012\hspace{0.33em}{\rm{au}} up to several months at r = 1 au r=1\hspace{0.33em}{\rm{au}} . The oscillations are characterized by pulsations of the MFT’s characteristics including its temperature. We argue that the oscillations can produce observed IR-variability of HAeBeSs, which would be more intense than in the case of T Tauri stars, since the disks of HAeBeSs are hotter, denser, and have stronger magnetic field.
赫比格Ae/Be星吸积盘中磁通管的动力学
考虑吸积盘中的浮力和阻力、与周围气体的辐射热交换以及吸积盘中的磁场,建立了典型赫比格Ae/Be星(HAeBeS)吸积盘中磁通管(MFTs)的动力学模型。利用我们的磁流体动力学模型模拟了圆盘的结构,并考虑了恒星辐射对圆盘表层的加热。模拟结果表明,mft周期性地从圆盘最内层区域上升,速度可达10-12 km s−1 {{\rm{s}}}^{-1}。在磁碟表面附近的外磁场作用下,MFTs经历衰减的磁振荡。振荡周期随着与恒星的距离和MFT初始等离子体β的增加而增加,从r=0.012 au时的几个小时r=0.012\hspace{0.33em}{\rm{au}}到r=1 au时的几个月r=1\hspace{0.33em}{\rm{au}}。振荡的特征是MFT的特征(包括其温度)的脉动。我们认为,振荡可以产生观测到的HAeBeSs红外变化率,这种变化率将比金牛座T星的情况更强烈,因为HAeBeSs的圆盘更热,密度更大,磁场更强。
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来源期刊
Open Astronomy
Open Astronomy Physics and Astronomy-Astronomy and Astrophysics
CiteScore
1.30
自引率
14.30%
发文量
37
审稿时长
16 weeks
期刊介绍: The journal disseminates research in both observational and theoretical astronomy, astrophysics, solar physics, cosmology, galactic and extragalactic astronomy, high energy particles physics, planetary science, space science and astronomy-related astrobiology, presenting as well the surveys dedicated to astronomical history and education.
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