The Relationship between Supernova Explosions and Black Hole Formation

Yiting Wang

doi:10.62051/42kdbj30

Authors

Yiting Wang

DOI:

https://doi.org/10.62051/42kdbj30

Keywords:

Supernova, black-hole, stellar collapse, black-hole formation, supernova explosion.

Abstract

The interaction between supernova explosions and black hole formation is a significant study in astrophysics, explaining the map of cosmic evolution. This study delves into the late stages of a star's life cycle, the evolution of white dwarfs and neutron stars, and the early stages of black hole formation. Through the fusion of theory and data observation, the study has deepened the understanding of stellar evolution cycles and revealed the complex process of black hole origin, as well as the internal and external conditions required for its formation (such as binary star systems with certain conditions). In addition, the study revealed that the principles of quantum mechanics are the foundation of celestial evolution, elucidating how the Pauli exclusion principle explains the transition from white dwarfs to neutron stars and ultimately to black holes based on stellar mass. By analyzing these phenomena, the profound connection between celestial evolution and the principles of quantum mechanics is emphasized, and this study helps to broaden the horizons of astrophysical exploration.

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