On the Origin of Long-term Modulation in the Sun’s Magnetic Activity Cycle

The Astrophysical Journal Letters Pub Date : 2025-04-23 DOI:10.3847/2041-8213/adc91e

Chitradeep Saha, Suprabha Mukhopadhyay, Dibyendu Nandy

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Abstract

One of the most striking manifestations of orderly behavior emerging out of complex interactions in any astrophysical system is the 11 yr cycle of sunspots. However, direct sunspot observations and reconstructions of long-term solar activity clearly exhibit amplitude fluctuations beyond the decadal timescale, which may be termed as supradecadal modulation. Whether this long-term modulation in the Sun’s magnetic activity results from nonlinear mechanisms or stochastic perturbations remains controversial and a matter of active debate. Utilizing multimillennial-scale kinematic dynamo simulations based on the Babcock–Leighton paradigm—in the likely (near-critical) regime of operation of the solar dynamo—we demonstrate that this supradecadal modulation in solar activity cannot be explained by nonlinear mechanisms alone; stochastic forcing is essential for the manifestation of observed long-term fluctuations in the near-critical dynamo regime. Our findings substantiate some independent observational and theoretical investigations and provide additional insights into temporal dynamics associated with a plethora of natural phenomena in astronomy and planetary systems arising from weakly nonlinear, nondeterministic processes.

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太阳磁活动周期长期调制的起源

在任何天体物理系统中，从复杂的相互作用中产生的有序行为的最引人注目的表现之一是太阳黑子的11年周期。然而，对太阳黑子的直接观测和对长期太阳活动的重建清楚地显示出超出年代际时间尺度的幅度波动，这可称为超年代际调制。太阳磁活动的这种长期调制是由非线性机制还是随机扰动引起的，仍然存在争议和积极的争论。利用基于Babcock-Leighton范式的多千年尺度的运动发电机模拟-在太阳发电机的可能（近临界）运行状态下-我们证明了太阳活动的这种超年代化不能仅用非线性机制来解释；随机强迫对于在近临界状态下观测到的长期波动的表现是必不可少的。我们的发现证实了一些独立的观测和理论研究，并为天文学和行星系统中由弱非线性、不确定性过程产生的大量自然现象相关的时间动力学提供了额外的见解。

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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The Astrophysical Journal Letters

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