Aims. An extremely large filament was studied in various layers of the solar atmosphere. The inferred physical parameters and the morphological aspects are compared with smaller quiescent filaments. Methods. A giant quiet-Sun filament was observed with the high-resolution Echelle spectrograph at the Vacuum Tower Telescope at Observatorio del Teide, Tenerife, Spain, on 2011 November 15. A mosaic of spectra (ten maps of 100″ × 182″ ) was recorded simultaneously in the chromospheric absorption lines H α and Na? i D _(2) . Physical parameters of the filament plasma were derived using cloud model (CM) inversions and line core fits. The spectra were complemented with full-disk filtergrams (He? i λ 10830 ?, H α , and Ca? ii ?K) of the Chromospheric Telescope (ChroTel) and full-disk magnetograms of the Helioseismic and Magnetic Imager (HMI). Results. The filament had extremely large linear dimensions ( ~ 817 arcsec), which corresponds to about 658 Mm along a great circle on the solar surface. A total amount of 175119 H α contrast profiles were inverted using the CM approach. The inferred mean line-of-sight (LOS) velocity, Doppler width, and source function were similar to previous works of smaller quiescent filaments. However, the derived optical thickness was higher. LOS velocity trends inferred from the H α line core fits were in accord but weaker than those obtained with CM inversions. Signatures of counter-streaming flows were detected in the filament. The largest brightening conglomerates in the line core of Na? i D _(2) coincided well with small-scale magnetic fields as seen by HMI. Mixed magnetic polarities were detected close to the ends of barbs. The computation of photospheric horizontal flows based on HMI magnetograms revealed flow kernels with a size of 5–8 Mm and velocities of 0.30–0.45 km s ~(-1) at the ends of the filament. Conclusions. The physical properties of extremely large filaments are similar to their smaller counterparts, except for the optical thickness, which in our sample was found to be higher. We found that a part of the filament, which erupted the day before, is in the process of reestablishing its initial configuration.
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机译:目的在太阳大气的各层中研究了一根非常大的灯丝。将推断的物理参数和形态方面与较小的静态细丝进行比较。方法。 2011年11月15日,在西班牙特内里费岛泰德天文台的真空塔望远镜上,用高分辨率的埃歇尔光谱仪观察到一条巨大的宁静太阳丝。记录到光谱的马赛克(100张×182张十张图)同时在色球吸收线Hα和Na 2中我D _(2)。细丝等离子体的物理参数是使用云模型(CM)反演和线芯拟合得出的。光谱还与色球望远镜(ChroTel)的全盘滤波图(He?iλ10830?,Hα和Ca?ii?K)以及Helioseismic and Magnetic Imager(HMI)的全盘磁图作了补充。结果。灯丝的线性尺寸非常大(约817 arcsec),相当于沿太阳表面大圆的大约658 Mm。使用CM方法反转了总计175119 Hα的对比曲线。推断的平均视线(LOS)速度,多普勒宽度和源函数与较小的静态细丝的先前工作相似。但是,导出的光学厚度较高。从Hα线岩心拟合推断出的LOS速度趋势是一致的,但比CM反演获得的弱。在细丝中检测到逆流流动的特征。 Na?线芯中最大的增白团块如HMI所示,i D _(2)与小规模磁场很好地吻合。在倒刺的末端附近检测到混合的磁极性。基于HMI磁图的光球水平流计算表明,流丝的直径为5–8 Mm,在细丝末端的速度为0.30–0.45 km s〜(-1)。结论。极长的灯丝的物理特性与较小的灯丝相似,除了光学厚度不同(在我们的样本中发现更高)。我们发现前一天喷出的细丝的一部分正在重建其初始构型。
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