恒星磁活动的尺度和演化

IF 9.1 2区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS

Space Science Reviews Pub Date : 2023-10-30 DOI:10.1007/s11214-023-01016-3

Emre Işık, Jennifer L. van Saders, Ansgar Reiners, Travis S. Metcalfe

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引用次数: 1

摘要

磁活动是具有对流外层的恒星的普遍特征，从恒星演化到行星大气都有影响。研究从几天到数十亿年观测到的恒星活动信号的机制，对于加深我们对包括太阳在内的恒星发电机的空间结构和时间模式的理解非常重要。在本文中，我们重点讨论了三个问题及其可能的解决方案。我们从直接的磁场测量开始，并展示它们如何探测磁通量及其密度对恒星特性和活动指标的依赖。接下来，我们回顾了当前基于物理的光球活动模式模型及其从旋转到活动周期时间尺度的变化。然后，我们概述了目前对恒星发电机长期演化的理解状态，首先使用色球和日冕活动诊断，然后使用基于模型的磁制动影响，这是恒星随着年龄增长而旋转并变得不活跃的关键机制。最后，我们讨论了改进恒星磁场建模和分析的可能方向。

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Scaling and Evolution of Stellar Magnetic Activity

Abstract Magnetic activity is a ubiquitous feature of stars with convective outer layers, with implications from stellar evolution to planetary atmospheres. Investigating the mechanisms responsible for the observed stellar activity signals from days to billions of years is important in deepening our understanding of the spatial configurations and temporal patterns of stellar dynamos, including that of the Sun. In this paper, we focus on three problems and their possible solutions. We start with direct field measurements and show how they probe the dependence of magnetic flux and its density on stellar properties and activity indicators. Next, we review the current state-of-the-art in physics-based models of photospheric activity patterns and their variation from rotational to activity-cycle timescales. We then outline the current state of understanding in the long-term evolution of stellar dynamos, first by using chromospheric and coronal activity diagnostics, then with model-based implications on magnetic braking, which is the key mechanism by which stars spin down and become inactive as they age. We conclude by discussing possible directions to improve the modeling and analysis of stellar magnetic fields.

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来源期刊

Space Science Reviews 地学天文-天文与天体物理

CiteScore

19.70

自引率

3.90%

发文量

审稿时长

4-8 weeks

期刊介绍： Space Science Reviews (SSRv) stands as an international journal dedicated to scientific space research, offering a contemporary synthesis across various branches of space exploration. Emphasizing scientific outcomes and instruments, SSRv spans astrophysics, physics of planetary systems, solar physics, and the physics of magnetospheres & interplanetary matter. Beyond Topical Collections and invited Review Articles, Space Science Reviews welcomes unsolicited Review Articles and Special Communications. The latter encompass papers related to a prior topical volume/collection, report-type papers, or timely contributions addressing a robust combination of space science and technology. These papers succinctly summarize both the science and technology aspects of instruments or missions in a single publication.