Possible Origin of Some Periodicities Detected in Solar‐Terrestrial Studies: Earth's Orbital Movements

Periodicities matching planetary cycles have been argued to be detected in key geophysical time series. In general, these periodicities were indirectly attributed to a planetary influence on solar activity. This supposes that planetary gravity affects the internal functioning of the Sun's dynam...

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Bibliographic Details
Published inEarth and space science (Hoboken, N.J.) Vol. 8; no. 8
Main Authors Cionco, R. G., Kudryavtsev, S. M., Soon, W. W.‐H.
Format Journal Article
LanguageEnglish
Published Hoboken John Wiley & Sons, Inc 01.08.2021
American Geophysical Union (AGU)
Subjects
4934
4946
5744
7536
Cosmic rays
Gravity effects
Hypotheses
Rivers
Solar activity
Solar cycle
Sun
Terrestrial environments
Time series
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Summary:Periodicities matching planetary cycles have been argued to be detected in key geophysical time series. In general, these periodicities were indirectly attributed to a planetary influence on solar activity. This supposes that planetary gravity affects the internal functioning of the Sun's dynamo, that is, the planetary hypothesis (PH) of the solar cycles. The Earth's heliocentric dynamics already includes the planetary gravitational effects on the Sun. Taking into account this fact, these periodicities, ultimately attributed to possible planetary modulations of the solar activity, could have a more direct origin in cyclical changes in the relative Sun‐Earth geometry, but then, wrongly or partially explained invoking internal solar changes. We present an original decomposition analysis of the high‐precision ephemeris DE431 from NASA/JPL in order to obtain and classify the most important planetary/lunar purely periodic changes of the Earth's orbital movement at sub‐Milanković scales. A comprehensive list of cyclic changes of the Earth's orbital parameters involved in the relative Sun‐Earth position and the Earth's speed around the Sun is given. We show that these particular geophysical quasi‐periods are identifiable in the cyclic oscillations of these orbital parameters. Since the Earth's movement in space physically affects the manner in which the solar radiant flux reaches the planet, these oscillations provide, unlike the PH, a clear, causal, and testable link for their possible attribution. Key Points Planetary cycles have been argued to be detected in key geophysical time series and attributed to planetary influence on solar activity These quasi‐periods can be identified in the oscillations of the Earth's orbital movement, which directly modulate incoming solar fluxes A hypothesis that some of these quasi‐periods could be fully or partially originated in changes of the Sun‐Earth geometry is put forth
ISSN:2333-5084
2333-5084
DOI:10.1029/2021EA001805