Difference between a Gravity Well and a Black Hole

In summary: Hawking_radiationIn summary, a Gravity Well and a Black Hole are both terms used to describe the gravitational field around astronomical objects. However, a Black Hole is a specific type of Gravity Well, where the gravitational pull is so strong that even light cannot escape. While Gravity Wells have a smooth and flat "bottom," a Black Hole has a singularity at its center. Black Holes can be formed through various means, including the collapse of a single star or the collision of two neutron stars. They are not completely black, as they emit a small amount of radiation known as Hawking radiation.
  • #1
Dave Hooley
1
0
I’m looking for the difference between a Gravity Well and a Black Hole, a Gravity Well (collapsed star) suggest that there is a bottom or end to it where there is a solid bottom or middle, and a Black Hole (unknown entity) suggest that there is no end only a constant ebb and flow with in the sphere where there is no solid’s and time maybe distorted, fore this is a human measurement and space maybe folded. I am trying to think dimensionally about this?
Thanks
Dave
 
Astronomy news on Phys.org
  • #2
Hmm... are you saying a black hole is not a collapsed star? What is it then?
 
  • #3
Originally posted by Dave Hooley
I?m looking for the difference between a Gravity Well and a Black Hole, a Gravity Well (collapsed star) suggest that there is a bottom or end to it where there is a solid bottom or middle, and a Black Hole (unknown entity) suggest that there is no end only a constant ebb and flow with in the sphere where there is no solid?s and time maybe distorted, fore this is a human measurement and space maybe folded. I am trying to think dimensionally about this?
Thanks
Dave

I don't think you'll ever find reference to a "gravity well" in any GR textbook or journal. It's a popular science term (promoted by Star Trek, among other sci-fi sources).

My take on 'gravity well' is that it's a way to describe the embedding diagram (i.e. the "sunken sheet") of a spherical gravitational source (star, planet, etc...). The bottom of this "well" is smooth and flat.

A black hole is a very special type of such a diagram, in which the center is a singularity (pointy).
 
  • #4
Originally posted by Dave Hooley
I’m looking for the difference between a Gravity Well and a Black Hole, a Gravity Well (collapsed star) suggest that there is a bottom or end to it where there is a solid bottom or middle, and a Black Hole (unknown entity) suggest that there is no end only a constant ebb and flow with in the sphere where there is no solid’s and time maybe distorted, fore this is a human measurement and space maybe folded. I am trying to think dimensionally about this?
Thanks
Dave

The term gravity well refers to the potential energy function near a gravitating body. Near a black hole it just happens to be very strong.

The Earth has a gravity well proportional to 1/r which extends from infinity to the surface of the Earth. Then it changes from a 1/r potential to a linear potential becoming zero at the center of the Earth.
 
  • #5
Originally posted by Tail
Hmm... are you saying a black hole is not a collapsed star? What is it then?

Some black holes are the result of a single star collapsing. Some aren't. E.g. supermassive black holes such as those at the center of galaxies are not the result of a single star collapsing. Mini/micro Black holes are also not the result of a star collapsing
 
  • #6
Welcome to Physics Forums, Dave.

I agree with the others on this. A "gravity well" is a non-technical term used to describe the gravitational field around an astronomical object (moon, planet, star). I mostly recall hearing that term in sci-fi (excuse me, "SF") stories with spaceships navigating their way around the universe. A black hole is a singularity, which like any other mass, has a gravitational field around it...a deep gravity well with a point of no return.
 
  • #7
Originally posted by pmb_phy
Some black holes are the result of a single star collapsing. Some aren't. E.g. supermassive black holes such as those at the center of galaxies are not the result of a single star collapsing. Mini/micro Black holes are also not the result of a star collapsing
I might be wrong, but I do think that at least most, if not all, black holes form due to a star collapsing (except for primordial black holes perhaps).
 
  • #8
Gravity well is a phrase coined by some jumped up hippy in the science fiction world.

A black hole is a consequence of the Schwarzschild metric. In GR the Schwarzschild metric is a solution to the Einstein equation. Where R=2GM a black hole occurs. It has this name as one cannot observe further than the event horizon.
 
Last edited:
  • #9
Black holes are formed by anything massive enough to stop light from radiating from escaping.

Two neutron stars coliding
Two other black holes
Large star goes nova
Thats all i can think of now
 
  • #10
Why The Black Wholes Are Not So Black?
 
  • #11
Nice coder said:
Large star goes nova

nitpick...
"supernova", not "nova"

supernova = large star that explodes during its end phase...the remaining core collapses into a neutron star or a black hole

nova = sudden brightening of a star (usually caused by accreting material from a companion star)
 
  • #12
MAYUKH said:
Why The Black Wholes Are Not So Black?

Welcome to Physics Forums, MAYUKH!

"Black" means that it emits no radiation (visible light, heat, whatever).

Black holes are not 100% black because they do emit a small amount of radiation due to a strange feature of virtual particles (see "Hawking Radiation").
 
  • #13
Hmm... I thought the point was they DON'T emit it? A black hole loses mass, but never emits any... that's the good part. :rolleyes: :biggrin:
 
  • #14
Oh no they do emit mass. Consider a pair of particles on "borrowed time" being created around a black hole, one forms inside the event horizon, the other outside. One can escape and become "real" the other falls into the hole and the black hole loses energy and we see the other particle being emitted.
 
  • #15
Hawking radiation of a black hole is a rather slow process and for most is insignificant but never the less present.
 
  • #16
Well, nothing goes OUT of the black hole, it's impossible, just particles with negative energy go in. Or so I understand it.
 
Last edited:
  • #17
First of all there are no particles with negative energy and secondly the Hawking radiation is a means of extracting some energy from the black hole. You can read up on Hawking radiation here http://casa.colorado.edu/~ajsh/hawk.html.
 
  • #18
Obviously, I meant virtual particles (by the way, Hawking mentions situations where real particles have negative energy). I agree that because of Hawking radiation a black hole gets smaller, its mass/energy decreases, just nothing gets out of it. It's all about quantum fluctuations. I suggest reading "Black Holes Ain't So Black", chapter 7 of A Brief History Of Time by Stephen Hawking.
 
  • #19
Nice coder said:
Black holes are formed by anything massive enough to stop light from radiating from escaping.

Two neutron stars coliding
Two other black holes
Large star goes nova
Thats all i can think of now
I think a black hole can form anywhere a sufficiently high mass density accumulates in space. At first, the mass does not have to occur within a singularity. It can appear to be ordinary space to someone "drifting in." Of course, it takes a lot of mass to create this sort of black hole, but it behaves like other black holes in that once you're in, you're in for keeps. :surprise:

Jerry Abbott
 
  • #20
nothing goes OUT of a black hole? Or maybe the energy get forced into another dimension? Can a gravity well create enough energy to warp space time and create a black hole or dimensional portal? Just a thought.
 
  • #21
LightSpread said:
nothing goes OUT of a black hole? Or maybe the energy get forced into another dimension? Can a gravity well create enough energy to warp space time and create a black hole or dimensional portal? Just a thought.

First of all, this post is 7 years old. In the top left of each persons post you can find the date of the post right above their name. Typically it is frowned upon to reply to an extremely old post, as most of those posters are probably not here anymore.

Anyways, the current view is that everything that goes into a black hole stays there other than the Hawking Radiation that is believed to be emitted by a Black Hole. A black hole IS a gravity well, just like the Earth or the sun is. The difference is the amount of mass is much much greater and compacted into a very very small area.
 

FAQ: Difference between a Gravity Well and a Black Hole

What is a gravity well?

A gravity well is a region in space where the gravitational pull of a massive object, such as a planet or star, is so strong that it affects the motion of other objects around it. The deeper the gravity well, the stronger the gravitational pull.

What is a black hole?

A black hole is a region in space where the gravitational pull is so strong that nothing, including light, can escape from it. This happens when a massive star collapses in on itself, creating a singularity with infinite density and zero volume.

What is the main difference between a gravity well and a black hole?

The main difference between a gravity well and a black hole is the strength of the gravitational pull. In a gravity well, the pull is strong enough to affect the motion of objects, but not strong enough to trap light. In a black hole, the pull is so strong that even light cannot escape.

Can a gravity well turn into a black hole?

No, a gravity well cannot turn into a black hole. A black hole is formed when a massive star collapses, creating a singularity. A gravity well is simply a region of space with a strong gravitational pull, and it does not have the same extreme properties as a black hole.

What happens to time near a gravity well or a black hole?

Time is affected by the strong gravitational pull near a gravity well or a black hole. This phenomenon, known as time dilation, causes time to pass slower near these objects compared to a reference point far away. The closer an object is to the gravity well or black hole, the slower time will pass for that object.

Back
Top