Heavy Elements Abundances Inferred from the First Adiabatic Exponent in the Solar Envelope

IF 2.7 3区物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS

Solar Physics Pub Date : 2024-10-10 DOI:10.1007/s11207-024-02384-x

Vladimir A. Baturin, Anna V. Oreshina, Gaël Buldgen, Sergey V. Ayukov, Victor K. Gryaznov, Igor L. Iosilevskiy, Arlette Noels, Richard Scuflaire

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Abstract

The first adiabatic exponent profile, noted \({{\Gamma }_{1}}\), computed along adiabatic coordinates (\(T\), \(\rho \)), is in the focus of our study. Under conditions of almost fully ionized hydrogen and helium, the \({{\Gamma }_{1}}\) profile is quite sensitive to heavy elements ionization. \({{\Gamma }_{1}}\) decreases in regions where an element is partially ionized. The recent helioseismic structural inversion is obtained with an accuracy better than \({{10}^{-4}}\) in the most of the adiabatic convective zone that allows to study ionization variations. The aim is to determine the major heavy elements content in the solar convective zone. The method of our research is synthesis of the \(\Gamma _{1}\) profile, which is based on a linear combination of the contributions of individual heavy elements. The idea of the approach was proposed and justified by Baturin et al. (2022). We find the best approximation of the inverted profile \({{\Gamma }_{1}}\) adjusting the abundances of major elements (C, N, O, Ne), meanwhile the abundances of elements heavier than neon are fixed. We synthesize the theoretical \({{\Gamma }_{1}}\) profile using the SAHA-S equation of state, and are able to reproduce the inverted profiles with an accuracy of \((1-2)\cdot {{10}^{-5}}\). Total mass fraction of heavy elements found with this method is \(Z=0.0148\pm 0.0004\). The oxygen logarithmic abundance is \(8.70\pm 0.03\), carbon \(8.44\pm 0.04\), nitrogen \(8.12\pm 0.08\), and neon \(8.17\pm 0.09\). The obtained estimations of oxygen and carbon agree with spectroscopic abundances by Asplund, Amarsi, and Grevesse (2021).

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从太阳包层第一绝热指数推断出的重元素丰度

沿绝热坐标（\(T\), \(\rho \)）计算的第一个绝热指数剖面是我们研究的重点。在氢和氦几乎完全电离的条件下，\({\γ }_{1}}\)剖面对重元素电离相当敏感。在元素部分电离的区域，\({{\Gamma }_{1}}\)会减小。最近的日震结构反演在绝热对流区的大部分地区获得了优于\({{10}^{-4}}\)的精度，从而可以研究电离的变化。目的是确定太阳对流区的主要重元素含量。我们的研究方法是合成 \(\Gamma _{1}\)剖面，它基于单个重元素贡献的线性组合。这种方法的理念是由 Baturin 等人（2022 年）提出并论证的。我们通过调整主要元素（C、N、O、Ne）的丰度，同时固定比氖更重的元素的丰度，找到了倒曲线 \({{\Gamma }_{1}}/)的最佳近似值。我们利用 SAHA-S 状态方程合成了理论 \({{\Gamma }_{1}}\) 剖面，并能够以 \((1-2)\cdot {{10}^{-5}}\) 的精度重现倒转剖面。用这种方法发现的重元素总质量分数为（Z=0.0148\pm 0.0004\）。氧的对数丰度为（8.70/pm 0.03），碳为（8.44/pm 0.04），氮为（8.12/pm 0.08），氖为（8.17/pm 0.09）。氧气和碳的估计值与 Asplund、Amarsi 和 Grevesse（2021 年）的光谱丰度一致。

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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来源期刊

Solar Physics 地学天文-天文与天体物理

CiteScore

5.10

自引率

17.90%

发文量

146

审稿时长

1 months

期刊介绍： Solar Physics was founded in 1967 and is the principal journal for the publication of the results of fundamental research on the Sun. The journal treats all aspects of solar physics, ranging from the internal structure of the Sun and its evolution to the outer corona and solar wind in interplanetary space. Papers on solar-terrestrial physics and on stellar research are also published when their results have a direct bearing on our understanding of the Sun.