The planetary theory of solar activity variability: a review

TL;DR

This review explores the hypothesis that planetary harmonics influence solar activity cycles, highlighting correlations, potential predictive models, and mechanisms by which weak planetary forces could affect the solar dynamo.

Contribution

It consolidates evidence for planetary influences on solar cycles, discusses mechanisms for force amplification, and evaluates predictive capabilities of planetary models.

Findings

Planetary harmonics cluster around main solar activity cycles.

Some planetary models can predict the phase of solar oscillations.

Weak tidal forces may be amplified in the solar core, affecting solar activity.

Abstract

Commenting the 11-year sunspot cycle, Wolf (1859, MNRAS 19, 85-86) conjectured that "the variations of spot frequency depend on the influences of Venus, Earth, Jupiter, and Saturn". The high synchronization of our planetary system is already nicely revealed by the fact that the ratios of the planetary orbital radii are closely related to each other through a scaling-mirror symmetry equation (Bank and Scafetta, Front. Astron. Space Sci. 8, 758184, 2022). Reviewing the many planetary harmonics and the orbital invariant inequalities that characterize the planetary motions of the solar system from the monthly to the millennial time scales, we show that they are not randomly distributed but clearly tend to cluster around some specific values that also match those of the main solar activity cycles. In some cases, planetary models have even been able to predict the time-phase of the solar oscillations including the Schwabe 11-year sunspot cycle. We also stress that solar models based on the hypothesis that solar activity is regulated by its internal dynamics alone have never been able to reproduce the variety of the observed cycles. Although planetary tidal forces are weak, we review a number of mechanisms that could explain how the solar structure and the solar dynamo could get tuned to the planetary motions. In particular, we discuss how the effects of the weak tidal forces could be significantly amplified in the solar core by an induced increase in the H-burning. Mechanisms modulating the electromagnetic and gravitational large-scale structure of the planetary system are also discussed.