The goal of this research is to explore the effects of black hole singularities. Methodology is to start with large objects like galaxies and continue to smaller objects within our solar neighbourhood. High-redshift o...The goal of this research is to explore the effects of black hole singularities. Methodology is to start with large objects like galaxies and continue to smaller objects within our solar neighbourhood. High-redshift observations from the James Webb Space Telescope reveal that distant galaxies and their central black holes formed shortly after the Big Bang. An innovation about the speed of light explains how supermassive black holes could have formed primordially. Predictions of Hawking radiation include the possibility of black holes contributing to the energy of stars such as the Sun. Black holes have also been suggested as a source of radiation and magnetic fields in giant planets. Observations of Enceladus raise the possibility that this moon and other objects near Saturn’s Rings contain small singularities. Extrapolations of this methodology indicate that black holes could exist within solar system bodies including planets. Extended discussion describes how their presence could explain mysteries of internal heat, planetary magnetic fields, and processes of solar system formation.展开更多
The original purpose of this research is to understand the origin and evolution of the Universe. I describe a simple cosmology that sheds light on the appearance of “dark” energy. Results explain the uniformity of t...The original purpose of this research is to understand the origin and evolution of the Universe. I describe a simple cosmology that sheds light on the appearance of “dark” energy. Results explain the uniformity of the cosmic microwave background, critical density, and other phenomena. Light continues to expand our understanding of the “dark” Universe, with applications to the microscopic quantum world.展开更多
文摘The goal of this research is to explore the effects of black hole singularities. Methodology is to start with large objects like galaxies and continue to smaller objects within our solar neighbourhood. High-redshift observations from the James Webb Space Telescope reveal that distant galaxies and their central black holes formed shortly after the Big Bang. An innovation about the speed of light explains how supermassive black holes could have formed primordially. Predictions of Hawking radiation include the possibility of black holes contributing to the energy of stars such as the Sun. Black holes have also been suggested as a source of radiation and magnetic fields in giant planets. Observations of Enceladus raise the possibility that this moon and other objects near Saturn’s Rings contain small singularities. Extrapolations of this methodology indicate that black holes could exist within solar system bodies including planets. Extended discussion describes how their presence could explain mysteries of internal heat, planetary magnetic fields, and processes of solar system formation.
文摘The original purpose of this research is to understand the origin and evolution of the Universe. I describe a simple cosmology that sheds light on the appearance of “dark” energy. Results explain the uniformity of the cosmic microwave background, critical density, and other phenomena. Light continues to expand our understanding of the “dark” Universe, with applications to the microscopic quantum world.
