Fingerprints of a Local Supernova

TL;DR

This paper presents evidence that a local supernova influenced the formation and composition of the solar system, affecting planetary formation, solar activity, and climate changes through nuclear and gravitational processes.

Contribution

It introduces a novel hypothesis linking local supernova debris to planetary formation, solar phenomena, and climate variations, supported by isotope and element analysis since 1960.

Findings

Meteorite and planetary element analysis reveals supernova fingerprints.

Solar core dynamics are influenced by planetary gravitational forces.

Solar activity and climate are affected by the supernova remnant depth.

Abstract

The results of precise analysis of elements and isotopes in meteorites, comets, the Earth, the Moon, Mars, Jupiter, the solar wind, solar flares, and the solar photosphere since 1960 reveal fingerprints of a local supernova (SN), undiluted by interstellar material. Heterogeneous SN debris formed the planets. The Sun formed on the neutron (n) rich SN core. The ground-state masses of nuclei reveal repulsive n-n interactions that trigger n-emission and a series of nuclear reactions that generate solar luminosity, the solar wind, and the measured flux of solar neutrinos. The location of the Sun's high-density core shifts relative to the solar surface as gravitational forces exerted by the major planets cause the Sun to experience abrupt acceleration and deceleration, like a yoyo on a string, in its orbit about the ever-changing centre-of-mass of the solar system. Solar cycles (surface magnetic activity, solar eruptions, and sunspots) and major climate changes arise from changes in the depth of the energetic SN core remnant in the interior of the Sun.