What type of celestial body is formed from the collapse of a massive star after a supernova explosion?

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Prepare for the Ontario Grade 9 Destreamed Science Exam with comprehensive quizzes, flashcards, and multiple-choice questions. Each question is supplied with hints and explanations to facilitate your learning experience. Ace your exam with confidence!

Multiple Choice

What type of celestial body is formed from the collapse of a massive star after a supernova explosion?

Explanation:
The collapse of a massive star after a supernova explosion can result in the formation of a neutron star, which is an incredibly dense remnant primarily composed of neutrons. When a star that has a mass greater than about 8 times that of our Sun exhausts its nuclear fuel, it undergoes a supernova explosion. The outer layers are expelled, while the core collapses under gravity. During this core collapse, if the remaining mass is between about 1.4 to 3 times the mass of the Sun, the core stabilizes into a neutron star. Neutron stars possess extraordinary properties, including extremely high densities—one teaspoon of neutron-star material would weigh around 6 billion tons—and strong magnetic fields. This structure results from the combination of gravity forcing protons and electrons to combine into neutrons. In contrast, if the remnant core exceeds about 3 solar masses, it continues to collapse and can form a black hole, which is another type of stellar remnant. A white dwarf, on the other hand, is formed from smaller stars (those less massive than our Sun) and represents a different endpoint in stellar evolution. A red giant phase occurs much earlier in a star's life cycle when it has not yet undergone supernova

The collapse of a massive star after a supernova explosion can result in the formation of a neutron star, which is an incredibly dense remnant primarily composed of neutrons. When a star that has a mass greater than about 8 times that of our Sun exhausts its nuclear fuel, it undergoes a supernova explosion. The outer layers are expelled, while the core collapses under gravity.

During this core collapse, if the remaining mass is between about 1.4 to 3 times the mass of the Sun, the core stabilizes into a neutron star. Neutron stars possess extraordinary properties, including extremely high densities—one teaspoon of neutron-star material would weigh around 6 billion tons—and strong magnetic fields. This structure results from the combination of gravity forcing protons and electrons to combine into neutrons.

In contrast, if the remnant core exceeds about 3 solar masses, it continues to collapse and can form a black hole, which is another type of stellar remnant. A white dwarf, on the other hand, is formed from smaller stars (those less massive than our Sun) and represents a different endpoint in stellar evolution. A red giant phase occurs much earlier in a star's life cycle when it has not yet undergone supernova

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