AESOPUS 2.1: Low-Temperature Opacities Extended to High Pressure

arXiv - PHYS - Solar and Stellar Astrophysics Pub Date : 2024-09-17 DOI:arxiv-2409.10905

Paola Marigo, Francesco Addari, Diego Bossini, Alessandro Bressan, Guglielmo Costa, Leo Girardi, Michele Trabucchi, Guglielmo Volpato

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Abstract

We address the critical need for accurate Rosseland mean gas opacities in high-pressure environments, spanning temperatures from 100 K to 32000 K. Current opacity tables from Wichita State University and AESOPUS 2.0 are limited to $\log(R) \le 1$, where $R=\rho\, T_6^{-3}$ in units of $\mathrm{g}\,\mathrm{cm}^{-3}(10^6\mathrm{K})^{-3}$. This is insufficient for modeling very low-mass stars, brown dwarfs, and planets with atmospheres exhibiting higher densities and pressures ($\log(R) > 1$). Leveraging extensive databases such as ExoMol, ExoMolOP, MoLLIST, and HITEMP, we focus on expanding the AESOPUS opacity calculations to cover a broad range of pressure and density conditions ($-8 \leq \log(R) \leq +6$). We incorporate the thermal Doppler mechanism and micro-turbulence velocity. Pressure broadening effects on molecular transitions, leading to Lorentzian or Voigt profiles, are explored in the context of atmospheric profiles for exoplanets, brown dwarfs, and low-mass stars. We also delve into the impact of electron degeneracy and non-ideal effects such as ionization potential depression under high-density conditions, emphasizing its notable influence on Rosseland mean opacities at temperatures exceeding $10,000$ K. As a result, this study expands AESOPUS public web interface for customized gas chemical mixtures, promoting flexibility in opacity calculations based on specific research needs. Additionally, pre-computed opacity tables, inclusive of condensates, are provided. We present a preliminary application to evolutionary models for very low-mass stars.

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AESOPUS 2.1：延伸至高压的低温不透明性

目前来自威奇托州立大学和AESOPUS 2.0的不透明度表仅限于$\log(R) \le1$，其中$R=\rho\, T_6^{-3}$，单位为$\mathrm{g}\, \mathrm{cm}^{-3}(10^6\mathrm{K})^{-3}$。这不足以模拟质量很低的恒星、褐矮星以及具有大气层、密度和压力较高的行星（$\log(R) > 1$）。利用ExoMol、ExoMolOP、MoLLIST和HITEMP等扩展数据库，我们重点扩展了AESOPUS的不透明度计算，以覆盖广泛的压力和密度条件（$-8 \log(R) \leq +6$）。我们纳入了热多普勒机制和微湍流速度。我们结合系外行星、褐矮星和低质量恒星的大气剖面，探讨了导致洛伦兹剖面或沃伊特剖面的分子转变的压力展宽效应。我们还深入研究了高密度条件下电子变性和电离势抑制等非边缘效应的影响，强调了其在温度超过 10,000 美元 K 时对罗瑟兰平均不透明度的显著影响。因此，本研究扩展了 AESOPUS 公共网络接口，可用于定制气体化学混合物，提高了基于特定研究需求的不透明度计算的灵活性。此外，还提供了包括冷凝物在内的预计算不透明度表。我们将初步应用于超低质量恒星的演化模型。

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arXiv - PHYS - Solar and Stellar Astrophysics

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