MINDS: The DR Tau disk. II. Probing the hot and cold H_2O reservoirs in the JWST-MIRI spectrum

M. Temmink, F. Ewine van Dishoeck, D. Gasman, L. Sierra Grant, B. Tabone, M. Gudel, Thomas K. Henning, D. Barrado, A. Caratti o Garatti, M. Adrian Glauser, I. Kamp, M. Aditya Arabhavi, H. Jang, N. Kurtovic, G. Perotti, K. Schwarz, M. Vlasblom
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Abstract

The Medium Resolution Spectrometer (MRS) of the Mid-InfraRed Instrument (MIRI) on the James Webb Space Telescope (JWST) gives insights into the chemical richness and complexity of the inner regions of planet-forming disks. Several disks that are compact in the millimetre dust emission have been found by Spitzer to be particularly bright in H_2O which is thought to be caused by the inward drift of icy pebbles. Here, we analyse the H_2O -rich spectrum of the compact disk DR Tau using high-quality JWST-MIRI observations. We infer the H_2O column densities (in cm$^ $) using methods presented in previous works, as well as introducing a new method to fully characterise the pure rotational spectrum. We aim to further characterise the abundances of H_2O in the inner regions of this disk and its abundance relative to CO . We also search for emission of other molecular species, such as CH_4 NH_3 CS H_2 SO_2 and larger hydrocarbons; commonly detected species, such as CO CO_2 HCN and C_2H_2 have been investigated in our previous paper. We first use 0D local thermodynamic equilibrium (LTE) slab models to investigate the excitation properties observed in different wavelength regions across the entire spectrum, probing both the ro-vibrational and rotational transitions. To further analyse the pure rotational spectrum (geq 10 $ mu $m), we use the spectrum of a large, structured disk (CI Tau) as a template to search for differences with our compact disk. Finally, we fit multiple components to characterise the radial (and vertical) temperature gradient(s) present in the spectrum of DR Tau. The 0D slab models indicate a radial gradient in the disk, as the excitation temperature (emitting radius) decreases (increases) with increasing wavelength, which is confirmed by the analysis involving the large disk template. To explain the derived emitting radii, we need a larger inclination for the inner disk ($i agreeing with our previous analysis on CO . From our multi-component fit, we find that at least three temperature components ($T_1 K, $T_2 K, and $T_3 K) are required to reproduce the observed rotational spectrum of H_2O arising from the inner $R_ em au. By comparing line ratios, we derived an upper limit on the column densities (in $) for the first two components of $ (N) within sim 1.2 au. We note that the models with a pure temperature gradient provide as robust results as the more complex models, which include spatial line shielding. No robust detection of the isotopologue H_2 ^ O can be made and upper limits are provided for other molecular species. Our analysis confirms the presence of a pure radial temperature gradient present in the inner disk of DR Tau, which can be described by at least three components. This gradient scales roughly as $ R_ em $ in the emitting layers, in the inner 2 au. As the observed H_2O is mainly optically thick, a lower limit on the abundance ratio of H_2O CO sim 0.17 is derived, suggesting a potential depletion of H_2O . Similarly to previous work, we detect a cold H_2O component ($T K) originating from near the snowline, now with a multi-component analysis. Yet, we cannot conclude whether an enhancement of the H_2O reservoir is observed following radial drift. A consistent analysis of a larger sample is necessary to study the importance of drift in enhancing the H_2O abundances.
MINDS: DR Tau 磁盘。II.探测 JWST-MIRI 光谱中的冷热 H_2O 储层
詹姆斯-韦伯太空望远镜(JWST)上的中红外光谱仪(MIRI)的中分辨率分光计(MRS)让人们了解到行星形成盘内部区域丰富而复杂的化学成分。斯皮策发现,一些在毫米尘埃发射中比较紧凑的星盘在 H_2O 中特别明亮,这被认为是冰卵石向内漂移造成的。在这里,我们利用高质量的 JWST-MIRI 观测数据分析了紧凑盘 DR Tau 的富含 H_2O 的光谱。我们利用以前工作中提出的方法推断出 H_2O 柱密度(单位:cm$^ $),并引入一种新方法来全面描述纯旋转光谱的特征。我们的目标是进一步确定该圆盘内部区域的 H_2O 丰度及其相对于 CO 的丰度。我们还搜索了其他分子物种的发射,如 CH_4 NH_3 CS H_2 SO_2 和更大的碳氢化合物;在我们之前的论文中已经研究了通常检测到的物种,如 CO CO_2 HCN 和 C_2H_2。我们首先使用 0D 局域热力学平衡 (LTE) 板坯模型来研究在整个光谱的不同波长区域观察到的激发特性,同时探究了旋转振动和旋转跃迁。为了进一步分析纯旋转光谱(geq 10 $ mu $m),我们使用了一个大型结构化圆盘(CI Tau)的光谱作为模板,以寻找与我们的紧凑圆盘的差异。最后,我们拟合了多个分量来描述 DR Tau 光谱中存在的径向(和垂直)温度梯度。0D板块模型表明,随着波长的增加,激发温度(发射半径)会降低(增加),因此在磁盘中存在径向梯度,这一点在涉及大磁盘模板的分析中得到了证实。为了解释得出的发射半径,我们需要一个更大的内盘倾角($i 与我们之前对 CO .通过多成分拟合,我们发现至少需要三个温度成分($T_1 K、$T_2 K 和 $T_3 K)才能重现观测到的来自内部 $R_ em au 的 H_2O 旋转光谱。通过比较线比,我们得出了模拟 1.2 au 范围内 $ (N) 的前两个分量的柱密度(单位:$)上限。我们注意到,纯温度梯度模型与包含空间线屏蔽的更复杂模型一样,都能提供可靠的结果。对同素异形体 H_2 ^ O 无法进行可靠的探测,但对其他分子种类提供了上限。我们的分析证实,DR Tau 的内盘存在纯径向温度梯度,至少可以用三个部分来描述。这个梯度在内部 2 au 的发射层中与 $ R_ em $ 大致成比例。由于观测到的 H_2O 主要是光厚型的,因此得出了 H_2O CO sim 0.17 的丰度比下限,这表明 H_2O 可能存在耗竭。与之前的工作类似,我们探测到了来自雪线附近的冷 H_2O 成分($T K),现在是多成分分析。然而,我们还不能断定在径向漂移之后是否观测到 H_2O 储层的增强。要研究漂移对提高 H_2O 丰度的重要性,需要对更大的样本进行一致的分析。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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