Hemispheric Asymmetry of Relative Sunspot Numbers during Solar Cycles 17–25

Hemispheric Asymmetry of Relative Sunspot Numbers during Solar Cycles 17–25

The hemispheric asymmetry of solar activity provides important diagnostics of solar dynamo processes. In this study, we present a phase-resolved statistical analysis of hemispheric sunspot number asymmetry over solar cycles 17–25 (1939–2024), using monthly mean data from the National Astronomical Ob...

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Bibliographic Details
Main Authors: Wenhua Wang, Linhua Deng, Zuo Jiang, Jinlei Li, Xinhua Zhao, Tingting Xu, Miao Wan, Jie Cao, Nanbin Xiang, Xuewen Tan, Wei Zhou, Weihong Zhou
Format: Article
Language:English
Published: IOP Publishing 2025-01-01
Series:The Astrophysical Journal Supplement Series
Subjects:
Sunspot number
Solar cycle
Solar magnetic fields
Online Access:https://doi.org/10.3847/1538-4365/adf105
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Summary:The hemispheric asymmetry of solar activity provides important diagnostics of solar dynamo processes. In this study, we present a phase-resolved statistical analysis of hemispheric sunspot number asymmetry over solar cycles 17–25 (1939–2024), using monthly mean data from the National Astronomical Observatory of Japan. By combining normalized asymmetry indices, cumulative deviation tracking, and year-by-year significance testing, we identify four key results: (1) the northern hemisphere consistently dominates during the ascending phases of most cycles, suggesting a preferential emergence of magnetic flux at the northern hemisphere; (2) the hemispheric asymmetry significantly diminishes during polarity reversal periods, indicating a balancing effect of global magnetic reconfiguration; (3) solar cycles 23 and 25 exhibit remarkably similar asymmetry patterns, implying solar cycle 25 is likely to be similar to solar cycle 23; and (4) the strength of hemispheric dominance correlates with the overall solar activity level, with stronger asymmetries observed during high-activity phases and weaker signals near solar minima. These findings offer new observational constraints for modeling hemispheric solar dynamics and establish a reproducible, scalable framework for future investigations of long-term solar magnetic asymmetries.
ISSN:0067-0049

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