How external photoevaporation changes the inner disc's chemical composition

Nelson Ndugu, Bertram Bitsch, Lienert Julia Lena
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Abstract

Stars mostly form in clusters where neighboring stars can influence proto-planetary disc evolution. Besides gravitational interactions, external photoevaporation can shape these discs. Depending on the strength of photoevaporation, discs can be destroyed within 1-2 Myrs or more gradually. We use the chemcomp code, incorporating a viscous disc evolution model with pebble drift and evaporation, to calculate the chemical composition of protoplanetary discs. This code is extended to include external photoevaporation based on the FRIED grid. Initially, the disc evolves purely viscously, with the inner disc's C/O ratio decreasing due to inward drifting and evaporating water ice pebbles. Over time, the C/O ratio increases as water vapor accretes onto the star and carbon-rich gas migrates inward. Once external photoevaporation starts, the outer disc disperses, but the inner disc's chemical evolution follows that of a purely viscous disc, as most pebbles have already drifted inward within 1 Myr. At low viscosity, the inner disc's C/O ratio remains sub-solar until dispersion by photoevaporation. At high viscosity, the C/O ratio can reach super-solar values, due to faster accretion of water vapor and inward migration of carbon-rich gas, provided the disc survives a few Myrs. In both cases, there is no significant difference in the inner disc's chemical composition compared to a purely viscous model due to the rapid inward drift of pebbles. Our model predicts that inner disc chemistry should be similar for discs subject to external photoevaporation and isolated discs, consistent with JWST observations.
外部光蒸发如何改变内圆盘的化学组成
恒星大多在星团中形成,邻近的恒星会影响原行星盘的演化。除了引力相互作用之外,外部光照蒸发也会塑造这些星盘。根据光热蒸发的强度,圆盘可能在 1-2 Myrs 内被摧毁,也可能逐渐被摧毁。我们使用 chemcomp 代码计算原行星圆盘的化学成分,该代码包含了一个具有鹅卵石漂移和蒸发的粘性圆盘演化模型。该代码基于FRIED网格进行了扩展,以包括外部光蒸发。最初,圆盘的演化纯粹是粘性的,由于向内漂移和水冰卵石的蒸发,内部圆盘的C/O比值下降。随着时间的推移,水蒸气吸积到恒星上,富碳气体向内迁移,C/O比值增加。一旦外部光蒸发开始,外圆盘就会消散,但内圆盘的化学演化与纯粘性圆盘相同,因为大多数卵石在 1 Myr 内就已经向内漂移了。在高粘度情况下,由于水蒸气的加速吸积和富碳气体的内移,C/O比值可以达到超太阳值,前提是圆盘能存活几个百万年。在这两种情况下,由于鹅卵石的快速内漂,内圆盘的化学成分与纯粘性模型相比没有显著差异。我们的模型预测,受外部光蒸发作用的圆盘和孤立的圆盘的内盘化学成分应该是相似的,这与 JWST 的观测结果是一致的。
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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