Orbit-Spin Coupling, the Solar Dynamo, and the Planetary Theory of Sunspots

TL;DR

This paper proposes orbit-spin coupling as a mechanism influencing solar variability, suggesting it can explain sunspot cycles and solar magnetic activity through planetary interactions affecting the Sun's internal dynamics.

Contribution

It introduces a novel orbit-spin coupling hypothesis as an alternative to tidal models, providing a physical basis for solar cycle variability linked to planetary orbital motions.

Findings

Estimated peak accelerations are about 100 times larger than tidal accelerations.

Torque values are provided from 1660 to 2220 AD for analysis.

A three-component model explains solar magnetic cycle variability.

Abstract

Orbit spin coupling is proposed as an alternative to planetary tidal models for the excitation of solar variability as a function of time. Momentum sourced from the orbital angular momenta of solar system bodies is deposited within the circulating fluid envelopes of the Sun and planets in this hypothesis. A reversing torque acts about an axis lying within the Sun's equatorial plane. The torque gives rise to tangential differential accelerations of solar materials as a function of longitude, latitude, depth, and time. The accelerations pulse in amplitude, and change sign, on timescales corresponding to the periods, beats, and harmonics of inner and outer planet orbital motions. In contrast to planetary tidal models, no special amplification mechanism may be required, as estimated peak accelerations are about 2 orders of magnitude larger than the largest tidal accelerations. Organized mass motions driven by the torque may be incorporated in dynamo simulations through the flow velocity term of the MHD induction equation. The spatiotemporal variability of flow velocities may then influence the variability with time of solar magnetic activity. We provide torque values at 1 day timesteps for the years 1660 to 2220. We discuss the time variability of the torque in juxtaposition with SIDC monthly sunspot numbers from 1750 to present. We investigate Hale cycle synchronization, and the variability with time of the total solar irradiance, with reference to outer and inner planet contributions respectively. We propose a 3 component model for understanding and simulating the solar magnetic cycle, which includes processes internal to the Sun, external forcing, due to orbit spin coupling, and a time-delay, or system memory, component. This model supplies a physical explanation for the observed variability with time of Schwabe cycle periods and Hale cycle periods from 1712 to present.