Evidence that 1.6-year solar quasi-biennial oscillations are synchronous with maximum Sun-planet alignments

TL;DR

This study suggests that the 1.6-year solar quasi-biennial oscillations are synchronized with planetary alignments, showing phase inversion between solar cycles, supported by new filtering and superposition methods.

Contribution

The paper introduces two novel methods to link solar activity oscillations with planetary alignments, providing evidence for their synchronization and potential for forecasting solar variability.

Findings

Strong correlation between planetary alignments and solar oscillations.

Phase inversion of oscillations explained by planetary alignment shifts.

Methods enable prediction of solar oscillation patterns.

Abstract

Solar quasi-biennial oscillations with period range 0.6 to 4 years, are prominent in records of solar activity. Here we show that the 1.6 year quasi-biennial oscillation in solar activity has the exceptional feature of phase inversion between each solar cycle in the sequence of four solar cycles, 20 to 23. The hypothesis advanced is that this feature is due to synchronicity between solar activity and planetary alignment. An index of alignment between Earth and Mercury, Venus, Jupiter and Saturn is shown to have dominant peaks of alignment separated by 1.6 years in each solar cycle with, however, peak alignments shifting by half a period, 0.8 years, between alternate solar cycles. Accepting that solar activity increases when planets align would explain the phase inversion in alternate solar cycles observed in the 1.6 year quasi-biennial oscillation. Two new methods were developed to test this hypothesis: (a) Narrow band filtering of solar activity with the pass band based on the frequency content of the planetary alignment index. (b) Superposing intervals of raw solar activity data centered on times of maximum planet alignment. Both methods provided strong support for the hypothesis. Planetary alignment is complex but predictable enabling the forecasting of solar oscillation intermittency and future oscillation spectral content.