In the context of stellar evolution, what typically occurs to high-mass stars at the end of their lifespan?

Unlock all questions

This demo includes only 20 questions. Upgrade to access hundreds of questions, flashcards, exam simulations, and disable ads.

Full question bankExam simulationsFlashcards
From $9.99Unlock all

Prepare for the ABCTE Biology Test with our quiz. Use flashcards and multiple-choice questions to enhance your understanding and increase your chances of success. All questions provide hints and detailed explanations. Get ready to excel in your biology exam!

Multiple Choice

In the context of stellar evolution, what typically occurs to high-mass stars at the end of their lifespan?

Explanation:
High-mass stars, typically those with a mass greater than approximately eight times that of the Sun, undergo a dramatic end to their lifecycle. After exhausting their nuclear fuel, these stars cannot support themselves against gravitational collapse. The core of a high-mass star collapses under its own gravity, leading to extreme temperatures and pressures. As a result, the outer layers of the star are expelled violently, resulting in a supernova explosion. This catastrophic event not only disperses elements into space, enriching the interstellar medium but also can leave behind a remnant core. Depending on the mass of the core left after the supernova, this remnant may become a neutron star or, if massive enough, even collapse further into a black hole. In contrast, other scenarios like becoming white dwarfs, shrinking into neutron stars, or turning into red giants are typical of lower-mass stars or represent different stages of stellar evolution that do not apply to high-mass stars at the end of their lifespan. This highlights the distinct evolutionary paths based on a star’s initial mass.

High-mass stars, typically those with a mass greater than approximately eight times that of the Sun, undergo a dramatic end to their lifecycle. After exhausting their nuclear fuel, these stars cannot support themselves against gravitational collapse. The core of a high-mass star collapses under its own gravity, leading to extreme temperatures and pressures.

As a result, the outer layers of the star are expelled violently, resulting in a supernova explosion. This catastrophic event not only disperses elements into space, enriching the interstellar medium but also can leave behind a remnant core. Depending on the mass of the core left after the supernova, this remnant may become a neutron star or, if massive enough, even collapse further into a black hole.

In contrast, other scenarios like becoming white dwarfs, shrinking into neutron stars, or turning into red giants are typical of lower-mass stars or represent different stages of stellar evolution that do not apply to high-mass stars at the end of their lifespan. This highlights the distinct evolutionary paths based on a star’s initial mass.

More Multiple Choice Questions
Subscribe

Get the latest from Examzify

You can unsubscribe at any time. Read our privacy policy