What prevents a star from collapsing under its own gravitational attraction?

AI Thread Summary
Stars resist collapsing under their own gravitational attraction due to several counteracting forces. In the sun, nuclear fusion generates heat and radiation pressure that maintain equilibrium against gravity. White dwarfs rely on electron degeneracy pressure, a quantum effect that prevents electrons from occupying the same space. Neutron stars experience a similar phenomenon known as neutron degeneracy pressure. These mechanisms are crucial for the stability of stars throughout their life cycles.
nlink1979
According to Newton's Law of Gravitation, all objects with mass attract one another. This law implies that all of the atoms that make up a star, such as our sun, are gravitationally attracted to one another. How is a star able to resist collapsing under its own gravitational attraction?

[?]

Nicole
 
Physics news on Phys.org
There are numerous interactions that counteract gravity, preventing such a collapse. In our sun, the process of nuclear fusion creates large amounts of heat and radiation; this radiation pressure keeps the star in equilibrium. In stars like white dwarfs, something called electron degeneracy pressure keeps the star from collapsing. This is a quantum effect that restricts the number of electrons we can squish into a certain volume, and acts to keep them apart. In neutron stars, a similar pressure arises from neutron degeneracy.
 
Thread 'Collision of a bullet on a rod-string system: query'

Thread 'Collision of a bullet on a rod-string system: query'

In this question, I have a question. I am NOT trying to solve it, but it is just a conceptual question. Consider the point on the rod, which connects the string and the rod. My question: just before and after the collision, is ANGULAR momentum CONSERVED about this point? Lets call the point which connects the string and rod as P. Why am I asking this? : it is clear from the scenario that the point of concern, which connects the string and the rod, moves in a circular path due to the string...
View full post »
Thread 'A cylinder connected to a hanged mass'

Thread 'A cylinder connected to a hanged mass'

Let's declare that for the cylinder, mass = M = 10 kg Radius = R = 4 m For the wall and the floor, Friction coeff = ##\mu## = 0.5 For the hanging mass, mass = m = 11 kg First, we divide the force according to their respective plane (x and y thing, correct me if I'm wrong) and according to which, cylinder or the hanging mass, they're working on. Force on the hanging mass $$mg - T = ma$$ Force(Cylinder) on y $$N_f + f_w - Mg = 0$$ Force(Cylinder) on x $$T + f_f - N_w = Ma$$ There's also...
View full post »

Similar threads

Introductory Physics - Finding "little g"
Replies
5
Views
3K
I Verse from "A Brief History of Time"
Replies
22
Views
1K
I Potential energy and the gravitational field of a collapsing cloud of gas
Replies
1
Views
1K
What Are the SI Units of the Gravitational Constant in Newton's Law?
Replies
4
Views
2K
Black holes/gravitational attraction
Replies
1
Views
2K
B What is the distinction between the Weak and Strong Equivalence Principles?
Replies
2
Views
2K
Having a hard time learning Newton's 2nd law
Replies
5
Views
2K
Conceptual questions about Newton's Laws....
Replies
15
Views
4K
I Why Does Gravity Remain when Star Mass Dissipates?
Replies
10
Views
2K
The Force of Gravity Depends on Two Masses
Replies
2
Views
2K

Hot Threads

Recent Insights

Back
Top