Light, Mass, and Black hole question

In summary, the concept of mass and relativistic mass can be complex when applied to particles with different rest masses, such as light. While particles with non-zero rest masses have a relativistic mass that increases as they approach the speed of light, light itself does not have a rest mass and therefore does not experience an infinite mass at the speed of light. The mass of light is related to its energy and frequency, and black holes have a finite mass but infinite density due to the compression of their mass into a singularity. It is important to define what is meant by mass when discussing it in relation to particles with different rest masses.
  • #1
Demiwing
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I heard from another thread that as u progress the speed of light, you'll eventually reach infinite mass. How come light itself don't reach infinite mass? And infinite mass means infinite gravitational force right? I heard there was a theory that the Black Hole has infinite mass, does that mean it is center of the universe? infinite gravational force means everytihng will eventually draw itself into it.
 
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  • #2
Seeing how it is assumed that almost 90 (not sure but it's something like that) percent of the mass of the universe is comprised of dark matter from which presumably black holes are made up of, I would think that black holes have that kind of gravitatinal force.

Off-topic: I heard something about time running 'slower' as you approach a black hole (maybe due to the high gravitational pulses it produces) which made me a little confused. Can someone elaborate?
 
  • #3
Demiwing said:
I heard from another thread that as u progress the speed of light, you'll eventually reach infinite mass. How come light itself don't reach infinite mass? And infinite mass means infinite gravitational force right? I heard there was a theory that the Black Hole has infinite mass, does that mean it is center of the universe? infinite gravational force means everytihng will eventually draw itself into it.

You have to be a bit careful about your wording here. The "relativistic mass" of a particle increases as it approaches the speed of light, but its "mass" or "invariant mass" stays constant.

So the situation is this: normal matter, with a non-zero rest mass, cannot achieve the speed of light. It's mass will remain constant with velocity, but its relativistic mass will increase as its velocity increases, approaching infinity at the speed of light.

Light, with a zero rest mass, cannot travel at any speed other than the speed of light. Light has no mass (no rest mass), but it does have a relativistic mass.

If you try to apply the mathematical formulas that apply to particles with a non-zero rest mass to light, you'd find that you multiply the inital zero rest mass of light by infinity to get light's "relativistic mass". This yields an undefined result. When you use the correct formulas, though, you find that light has a finite relativistic mass.

You might also find the sci.physics.faq "Does mass change with velocity" helpful in understanding this point.

http://math.ucr.edu/home/baez/physics/Relativity/SR/mass.html
 
  • #4
pervect said:
You have to be a bit careful about your wording here. The "relativistic mass" of a particle increases as it approaches the speed of light, but its "mass" or "invariant mass" stays constant.

So the situation is this: normal matter, with a non-zero rest mass, cannot achieve the speed of light. It's mass will remain constant with velocity, but its relativistic mass will increase as its velocity increases, approaching infinity at the speed of light.

Light, with a zero rest mass, cannot travel at any speed other than the speed of light. Light has no mass (no rest mass), but it does have a relativistic mass.

If you try to apply the mathematical formulas that apply to particles with a non-zero rest mass to light, you'd find that you multiply the inital zero rest mass of light by infinity to get light's "relativistic mass". This yields an undefined result. When you use the correct formulas, though, you find that light has a finite relativistic mass.

You might also find the sci.physics.faq "Does mass change with velocity" helpful in understanding this point.

http://math.ucr.edu/home/baez/physics/Relativity/SR/mass.html


Hmm... I see. But can someone elaborate on relativistic mass, invariant mass, and mass?
 
  • #5
Demiwing said:
Hmm... I see. But can someone elaborate on relativistic mass, invariant mass, and mass?

Did you read the URL I posted? It goes into some detail.
 
  • #6
for particles with a non-zero rest mass...
[tex] m = \frac{m_0}{\sqrt{1 - \frac{v^2/c^2}}} [/tex]
This equation gives you the mass of a particle relative to you, going at velocity v.

particles with a zero rest mass, for example, photons, naturaly travel at the speed of light, they cannot travel slower or faster that lightspeed relative to any frame. You are not allowed to use the equation i gave you to calculate relativistic mass of light, because special relativity equations don't work for anything that travels at lightspeed. It's clearly seen because the equation would yield 0/0, which is undefined. But like the others said light DOES have relativistic mass, which you can calculate using the mass-energy equivelance, E = mc^2.

The mass of light would be equal to E/c^2 or...
[tex] m = \frac{h\nu}{c^2}[/tex]
where h is planks constant and nu is frequency of the light.
 
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  • #7
Welcome to Physics Forums, Demiwing.

The mass-relativistic mass idea can be a complex one. Check out the link pervect mentioned. Plus, there are several past discussions on it in this forum.

Demiwing said:
I heard there was a theory that the Black Hole has infinite mass

No, black holes have a finite mass, which is based on how much stuff went into making it (e.g., the core of a dead star plus whatever falls into it). But that mass is compressed to zero volume (the singularity of the black hole), so it has infinite density. The finite gravity is still based on the finite mass.
 
  • #8
Demiwing said:
I heard from another thread that as u progress the speed of light, you'll eventually reach infinite mass.
Yep. But that really depends on what people mean when they use the term "mass." Some people use it to refer to m = inertial mass (which is a function of speed) and some people use it to refer to m0 = proper mass (which is not a function of speed). They are related by [itex]m = \gamma m_0[/itex]
How come light itself don't reach infinite mass?
You're trying to apply something to photons which applies to particles with non-zero rest mass. You get into trouble in this way. Mass is defined as the ratio m = p/v (mass = momentum/speed). Photons have a finite momentum and therefore have a finite mass. For particles which travel at speeds less than c the mass is a function of speed and as v-> c, m -> infinity.
And infinite mass means infinite gravitational force right?
Not neccesarily. Take a straight cosmic string as an example. The mass per unit length is enormous. Yet these objects don't exert any gravitational force on objects, even those which are right next to it.
I heard there was a theory that the Black Hole has infinite mass, ..
You heard wrong. Its possible to have a black hole of any mass. Mini black holes have a mass of Mt. Everest, and that's certainly not infinite.

However if you have a simply object like the Earth and you move relative to it then the gravitational force on an object will be a function of the speed of the Earth.
pervect said:
Light, with a zero rest mass, cannot travel at any speed other than the speed of light. Light has no mass (no rest mass), but it does have a relativistic mass.
pervect is referring to the speed of light as measured locally. The coordinate speed of light, i.e. v = dx/dt, depends on things like the strength of the gravitational field.
If you try to apply the mathematical formulas that apply to particles with a non-zero rest mass to light, you'd find that you multiply the inital zero rest mass of light by infinity to get light's "relativistic mass". This yields an undefined result. When you use the correct formulas, though, you find that light has a finite relativistic mass.
E.g. "relativistic mass" is defined as the m such that mv is a conserved quantity. p = mv is defined as the momentum. Anything with momentum will have a well defined mass.

Note: If an object is isolated and does not interact with anything else then the "inertial" energy E = Rest Energy + Kinetic Energy will be related to the mass m = p/v by E = mc2. However this relation does not hold in general. If there are external forces acting on the body, and thus giving it stress, then the mass will be a function of the stress in the body. In that situation p/v does not equal E/c2. This was shown by Einstein in a 1906 in fact, altough he addressed it in the form of the kinetic energy of the body.
Demiwing[/quote said:
Hmm... I see. But can someone elaborate on relativistic mass, invariant mass, and mass?
See -
http://www.geocities.com/physics_world/sr/inertial_mass.htm
http://www.geocities.com/physics_world/sr/invariant_mass.htm
Phobos said:
The mass-relativistic mass idea can be a complex one. Check out the link pervect mentioned. Plus, there are several past discussions on it in this forum.
Actually its quite simple; (relativistic) mass = m = m(v) is defined as m = p/v. Proper mass (aka rest mass) is defined as m(0). It can't get simpler than that.

Pete
 
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  • #9
Demiwing said:
I heard from another thread that as u progress the speed of light, you'll eventually reach infinite mass. How come light itself don't reach infinite mass? And infinite mass means infinite gravitational force right? I heard there was a theory that the Black Hole has infinite mass, does that mean it is center of the universe? infinite gravational force means everytihng will eventually draw itself into it.

Black holes do not ahve infinite mass, they have finite mass. Infinite density.

Light has no mass. It has energy and momentum, but no mass. It has an equivalent mass, but that is not its mass.
 
  • #10
franznietzsche said:
Light has no mass. It has energy and momentum, but no mass. It has an equivalent mass, but that is not its mass.
Such a statement is meaningless unless one first states the definition of mass. As many relativists define "mass" as m = p/v it follows that light has mass. You're speaking of proper mass which is something different.

Light has inertial mass mI (defined as that which gives matter a momentum) which, passive gravitational mass (that on which gravity acts) and active gravitational mass (that which generates a gravitational field). It has zero proper mass . What you've called "equivalent mass" is what many simply call "mass."

All this was all discussed above. Was there something in particular that you think was incorrect? If so then what is your basis for such a position beyond the semantics of arguing how a term is defined? Thanks.

Pete
 
  • #11
pmb_phy said:
Actually its quite simple; (relativistic) mass = m = m(v) is defined as m = p/v. Proper mass (aka rest mass) is defined as m(0). It can't get simpler than that.

Perhaps I should have qualified it as "a complex idea to someone new to Relativity".
 
  • #12
Phobos said:
Perhaps I should have qualified it as "a complex idea to someone new to Relativity".
I see it not so much a complex idea as one that is surprising, i.e. surprising as in the surprise one gets with time dilation and length contraction.

Re - " I heard there was a theory that the Black Hole has infinite mass, .."

I see this alot. It appears that people think that a black hole must have a lot of mass. This probably comes from the notion that some stars will collapse into a black hole. But what the student is forgetting is that before the collapse the star is stable and not collapsing and yet, if nothing else, the star is actually loosing mass. So if one really paid attention to all this they'd realize that all objects which collapse to a black hole always had that amount of mass or greater and at those times the star was not a black hole.

Pete
 

1. What is light?

Light is a form of electromagnetic radiation that is visible to the human eye. It is composed of particles called photons that have properties of both a wave and a particle.

2. What is mass?

Mass is a measure of the amount of matter in an object. It is a fundamental property of matter and is measured in units of kilograms (kg).

3. How are light and mass related?

Light and mass are related through the famous equation E=mc^2, where E represents energy, m represents mass, and c represents the speed of light. This equation shows that light and mass are interchangeable and can be converted into each other.

4. 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. It is formed when a massive star collapses in on itself, creating a singularity with infinite density.

5. How does a black hole affect light and mass?

A black hole's strong gravitational pull causes light to bend and distort as it passes by, a phenomenon known as gravitational lensing. It also has the ability to pull in and absorb nearby matter, including other stars and planets, due to its immense mass.

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