Is Mass Really Condensed Energy

In summary, A. Einstein contended that (E=mc2) energy was equal to mass X velocity of light squared. This raises questions about the relationship between mass and energy, and whether mass can be considered to be condensed energy. However, energy is not a tangible thing, but rather a property of a system, and its exact nature is still unknown. In physics, energy is defined as the ability of a system to do work, and it is conserved through an energy invariant conservation law. While relativity does not provide direct insights into the nature of energy, it does offer clues through its principles and equations.
  • #1
onycho
2
0
A. Einstein contended that (E=mc2) energy was equal to mass X velocity of light squared.

Does is it not follow that M=e/c2 or that mass is really condensed energy?

If mass is truly energy, then what is it that we observe from our mind's point of reference?

Finally what is energy?
 
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  • #2
In physics, energy is the ability of a system to do work.

http://en.wikipedia.org/wiki/Energy

Work is defined by force * distance (in an inertial frame)

If you consider particle / antiparticle reactions (say an electron and an anti-electron), you can see examples of how mass can be converted into energy. This does not mean, however, that the energy contained in a mass M is necessarily fully accessible to us. Generally, it is not accessible, unless we have access to a supply of antimatter of equal mass.

Anti-matter does not occur naturally (as far as we know) and has to be artifically produced. The amount of energy it takes to produce anti-matter is much more than the energy which it actually liberates.

As far as whether matter is "really" condensed energy, that's a bit philosophical. What experimental tests would convince you that it was? What experimental tests would convince you that it wasn't?
 
  • #3
onchyo, in simple terms:

Mass is a property of a thing. Imagine thing A is moving, and you want to slow it down. If it's massive then even if it's going slow, it has a lot of Mass, so you have to work real hard to slow it down.

Energy is also a property of a thing. Imagine thing B is moving, and you want to slow it down. If it ain't massive but it's going real fast, it has a lot of Kinetic Energy, so you have to work real hard to slow it down.

A and B have different properties, but these properties can sometimes look like one another. And they can be actually translated into one another for real. But I wouldn't say mass is condensed energy. Energy isn't a thing, it isn't something you can condense. It's just a property of a thing. It's like colour. It can't exist on its own. The thing exists. The motion exists. The energy does not. That's why it can't be created or destroyed. Because it doesn't exist in the first place.

What is energy? It's just a measure of how much change in motion the thing can achieve on another thing.
 
  • #4
onycho said:
A. Einstein contended that (E=mc2) energy was equal to mass X velocity of light squared.

Does is it not follow that M=e/c2 or that mass is really condensed energy?

If mass is truly energy, then what is it that we observe from our mind's point of reference?

Finally what is energy?
E = mc2 is a relationship between the energy supplied to a closed system and the quantity of mass increase of the system due to the added energy. It is also the maximum amount of energy a system can transfer to other systems, e.g. like the amount of rest energy possesed by a pion. The pion can disintegrate into two particles, the sum of the energies of the two particles adding up to the rest energy of the pion. Mass is not "frrozen energy."

What is energy? Nobody knows. This is a complicated question which deserves a complete answer. Unfortunately the answer is too long to post here. For that reason I made a web page to address this question. Please see

http://www.geocities.com/physics_world/mech/what_is_energy.htm

Note the comment by Feynman
It is important to realize that in physics today, we have no knowledge of what energy is. We do not have a picture that energy comes in little blobs of a definite amount. It is not that way. However, there are formulas for calculating some numerical quantity, and we add it all together it gives “28” - always the same number. It is an abstract thing in that it does not tell us the mechanism or the reasons for the various formulas.

Pete
 
  • #5
I don't believe this question belongs in a relativity forum. "What is mass" and "What is energy" are questions which should be discussed in general physics.

After those discussions are held, we can then ask - "now how does relativity affect these concepts". Relativity does little to shed light on the nature of mass and energy.
 
  • #6
actionintegral said:
I don't believe this question belongs in a relativity forum. "What is mass" and "What is energy" are questions which should be discussed in general physics.

After those discussions are held, we can then ask - "now how does relativity affect these concepts". Relativity does little to shed light on the nature of mass and energy.
The OT asked a question about the relationship between mass and energy, i.e. E = mc2 which is a relationship derived using tghe principles of special relativity. Hence this forum is the right forum to post this question.

Pete
 
  • #7
I know, but I wasn't trying to shut down the discussion. The big giant font
at the end of the question gave me the impression that the original poster was searching relativity for clues about the nature of energy. I was only pointing out that there was none to be found.
 
  • #8
onycho said:
A. Einstein contended that (E=mc2) energy was equal to mass X velocity of light squared.

Does is it not follow that M=e/c2 or that mass is really condensed energy?

If mass is truly energy, then what is it that we observe from our mind's point of reference?

Finally what is energy?

For me, energy makes sense only if you can define an energy invariant conservation law. Better, the energy conservation law is what define energy.
gijeqkeij
 
  • #9
actionintegral said:
I know, but I wasn't trying to shut down the discussion. The big giant font
at the end of the question gave me the impression that the original poster was searching relativity for clues about the nature of energy. I was only pointing out that there was none to be found.
I would say that there are clues in that there are properties of energy, but energy itself is quite undefinable as far as we know.

Pete
 
  • #10
Ditto for mass!
 
  • #11
actionintegral said:
Ditto for mass!
Why? Mass is a well defined quantity.

Pete
 
  • #12
pmb_phy said:
Why? Mass is a well defined quantity.

Pete

How mass can be a well defined quantity in GR if there is not a mass conservation law?
gijeqkeij
 
  • #13
gijeqkeij said:
How mass can be a well defined quantity in GR if there is not a mass conservation law?
gijeqkeij
Who says that there is no mass conservation law?? he conservation law for mass is identical to the conservation law of energy, i.e. Tuv;u = 0.

Pete
 
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  • #14
pmb_phy said:
Who says that there is no mass conservation law?? he conservation law for mass is identical to the conservation law of energy, i.e. Tuv;u = 0.

Pete

Pete, first of all we are now talking of energy and not only mass anymore; second Tuv;u = 0 is not a proper conservation law (that the reason for the energy pseudo-tensor and all the relevant discussion).

gijeqkeij
 
  • #15
gijeqkeij said:
Pete, first of all we are now talking of energy and not only mass anymore; ...
Huh? This is a thread on mass is it not? In anycase I was addressing you're assertion that mass can't be defined.
second Tuv;u = 0 is not a proper conservation law (that the reason for the energy pseudo-tensor and all the relevant discussion).
I don't see how you arrived at this assumption. Please clarify as to how you arrived at this assertion.

The equation I posted is standard GR stuff. Its actually called the conservation of energy-momentum (i.e. energy is conserved and momentum is conserved). Its called the Law of local energy-momentum conservation. See MTW page 386 if you have that text.

Thanks

Pete
 
  • #16
pmb_phy said:
The equation I posted is standard GR stuff. Its actually called the conservation of energy-momentum (i.e. energy is conserved and momentum is conserved). Its called the Law of local energy-momentum conservation. See MTW page 386 if you have that text.
Actually Pete Tuv;u = 0, the conservation of energy-momentum does not generally imply the conservation of energy and the conservation of momentum; those are frame dependent concepts and in a freely falling frame the separate total energy and momentum of another object, freely falling in a different part of the gravitational field will not themselves individually appear conserved.

The (-+++) nature of the metric means that the 3-momentum component is vector subtracted from the total energy to obtain the 4-momentum or energy-momentum of the object, and it is this resultant, which is the rest mass, that is conserved in GR.

This has the result that rulers remain of fixed length and clocks remain regular.

Garth
 
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  • #17
pmb_phy said:
Huh? This is a thread on mass is it not? In anycase I was addressing you're assertion that mass can't be defined.
I don't see how you arrived at this assumption. Please clarify as to how you arrived at this assertion.

Probably I was unclear: in GR you can only speak of energy conservation and not mass conservation...and also energy conservation in my opinion is not well defined.

pmb_phy said:
The equation I posted is standard GR stuff. Its actually called the conservation of energy-momentum (i.e. energy is conserved and momentum is conserved). Its called the Law of local energy-momentum conservation. See MTW page 386 if you have that text.

Yes I do have MTW; pls check page 466ff: in GR you can't localize the energy of gravitational fields... that means in general: no proper energy conservation law available and without a proper energy conservation law you can't define energy properly.

gijeqkeij
 
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  • #18
gijeqkeij said:
Probably I was unclear: in GR you can only speak of energy conservation and not mass conservation...
Since relativity considers energy and mass to be the same thing then I ask you on what do you base this assertion?
Yes I do have MTW; pls check page 466ff: in GR you can't localize the energy of gravitational fields... that means in general: no proper energy conservation law available and without a proper energy conservation law you can't define energy properly.
That is the energy of the gravitational field. I was speaking about the energy/mass of matter.

In any case I was responding to your comment
How mass can be a well defined quantity in GR if there is not a mass conservation law?
When I posted my assertion that mass is a well defined quantity I had in mind the mass of a particle (i.e. inertial mass), not a general definition of mass which encompasses all of GR (i.e. active and passive gravitational mass.

In any case I now understand what you meant when you said that mass is not conserved and I therefore have no more questions to ask you so I will bow out here so that this thread doesn't drone on about mass/energy conservation. Seems like many threads get sidetracked with conversations like this and end up donminating a thread. I don't wish to contribute to that in any threads, hence my bowing out. Thanks.

Garth - If you recall, we discussed your comments in the past ad nauseum and I understand that you have a different opinion on that point so I see no reason to go over the same discusssion again. Thanks.

Pete
 
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  • #19
pmb_phy said:
Since relativity considers energy and mass to be the same thing then I ask you on what do you base this assertion?
That is the energy of the gravitational field. I was speaking about the energy/mass of matter. Otherwise WTW would be contradictiing themselves.

Thanks

Pete

Probably we say the same things in different words. Let me rephrase: you can't actually distinguish in GR between mass, energy, energy of gravitational fields. That why you can't have in GR a proper energy conservation law... so mass and energy can't be well defined in GR.
gijeqkeij
 
  • #20
I would be interested in learning the definition of mass. Please post it.
 
  • #21
actionintegral said:
I would be interested in learning the definition of mass. Please post it.
It depends on what you mean by "mass." There are several meanings to the term: inertial mass (aka relativistic mass), proper mass, active gravitational mass and passive gravitational mass.

Inertial mass - The quantity m such that mv is a conserved quantity in elastic collisions. m is a function of speed, i.e. m = m(v).

Proper mass - For a tardyon m0 = m(0). For a luxon m0 = 0.

Active gravitational mass - That which is the source of a gravitational field.

Passive Gravitational mass - That which a gravitational field acts on.

For a detailed definition please see

http://www.geocities.com/physics_world/mass_paper.pdf

Pete
 
  • #22
I am basically with gijeqkeij and Garth on this issue, as long-time posters will probably be aware.

The way I describe mass in GR is not that there is no defintion, it is rather that there is no single definition. There are many different defintions of mass in GR, some of the more comon are

ADM mass, Bondi mass, and Komar mass. The first two are applicable in asymptotically flat space-times, and differ on how they handle energy in gravitational radiation. The last is applicable in any static space-time.

Other posters have talked briefly about other sorts of mass (such as Dixon mass), which I want to learn more about someday.

See

https://www.physicsforums.com/archive/index.php/t-110905.html

for some past discussion.If the space-time is neither static nor asymptotically flat, there is no general definition of mass in GR, just as there is no general definition of energy.
 
  • #23
Garth said:
Actually Pete Tuv;u = 0, the conservation of energy-momentum does not generally imply the conservation of energy and the conservation of momentum;
I was speaking about conservation of energy, not momentum. One would never assume that a quantity such as momentum is a constant of motion when it is moving in a gravitational field. The law of conservation of momentum applies only to those particles on which no force is acting. I.e. in Newtonian gravity a particle falling in the Earth's gravitational field (as observed by someone sitting on its surface) will measure the energy to be constant and yet the momentum will constantly changing when in free-fall. However since this is a static field then the energy of such a falling particle will be zero.
..those are frame dependent concepts and in a freely falling frame the separate total energy and momentum of another object, freely falling in a different part of the gravitational field will not themselves individually appear conserved.
Actually its a geometric property when external 4-forces are zero. The equation div T = 0 is a geometric statement, i.e. independant of spacetime coordinates. It is easily found by calculating in a locally Lorentzian frame. So while its true that energy is frame dependant it is not true that the Law of conservation is frame dependant. Its sort of like measuring proper mass. It is measured when the particle is at rest in a locally Lorentzian field. If one is evaluating the energy from a freely-falling frame in a curved spacetime then the field will be time independant and such a field is non-conservative.

Its not as if the GR community calls this "local" energy-momentum conservation for nothing Garth. They state it that way for a reason.
The (-+++) nature of the metric means that the 3-momentum component is vector subtracted from the total energy to obtain the 4-momentum or energy-momentum of the object, and it is this resultant, which is the rest mass, that is conserved in GR.
3-momentum is not vector subtracted from energy since one is a tensor of rank zero while the other is a tensor of rank one. The meaning of the equation you speak of (i.e. the T^0u_u = 0 equation) is a conservation equation which states that energy entering a small enclosed surface will equal the rate at which energy passes through the surface which is the rate at which energy decreases from external to the surface. Plus you can't add 4-vectors which are located at different events in spacetime. That is a violation of the rule for adding vectors. In any case, when the energy for a single particle in free-fall in a static g-field is calculated then the energy (E ~ P 0) it will be a constant of motion, i.e. conserved.

When one speaks of conservation laws one must take into account the specific example and see if it matches the condition postulated in the law. I.e. in that case "momentum" is rarely conserved since the law states that "The momentum of a free particle is conserved" and therefore you must take into account forces acting on a particle. Likewise the energy of a particle in a field is not constant unless the potential is time-independant, i.e. a conservative field.

Pete
 
  • #24
How would you explain black holes? I would like to think of mass and energy as states of existence which are not binary and rather a spectrum therefore providing the possibility of having a state that has both mass and energy.
Interestingly there is a Sanskrit verse "aapOHO vaa idhagum sarvam viswaa bhuthaanyApa". Sarvam viswaa means entire universe and aapoho means water. The gist of it roughly tries to suggest that entire universe is made of water. I found the meaning quite curious and happened to have a study at the literature. I was surprised to find what the folks were hinting at. The verse tries to suggest that entire universe existed in a liquid state. This liquid was churned and and from it arose time. I am assuming here the entire energy was churned to a single point of infinite energy to create a big bang which created time too.

I am astonished at the quality of thought that existed in these folks from the BCs with absolutely no equipments to verify even their basic theories.

Farsight said:
onchyo, in simple terms:

Mass is a property of a thing. Imagine thing A is moving, and you want to slow it down. If it's massive then even if it's going slow, it has a lot of Mass, so you have to work real hard to slow it down.

Energy is also a property of a thing. Imagine thing B is moving, and you want to slow it down. If it ain't massive but it's going real fast, it has a lot of Kinetic Energy, so you have to work real hard to slow it down.

A and B have different properties, but these properties can sometimes look like one another. And they can be actually translated into one another for real. But I wouldn't say mass is condensed energy. Energy isn't a thing, it isn't something you can condense. It's just a property of a thing. It's like colour. It can't exist on its own. The thing exists. The motion exists. The energy does not. That's why it can't be created or destroyed. Because it doesn't exist in the first place.

What is energy? It's just a measure of how much change in motion the thing can achieve on another thing.
 

1. Is mass really condensed energy?

The theory of relativity, proposed by Albert Einstein, states that mass and energy are interchangeable and are two forms of the same thing. This means that mass can be converted into energy and vice versa. Therefore, it can be said that mass is indeed condensed energy.

2. How can mass be converted into energy?

According to Einstein's famous equation, E=mc², mass can be converted into energy by multiplying the mass of an object by the speed of light squared. This shows the immense amount of energy that is contained within even a small amount of mass.

3. What is an example of mass being converted into energy?

A well-known example of mass being converted into energy is nuclear fusion, which occurs in the sun's core. In this process, hydrogen atoms combine to form helium, releasing a large amount of energy in the form of light and heat.

4. Can energy be converted back into mass?

Yes, energy can be converted back into mass. This process is known as pair production and occurs when a high-energy photon interacts with a nucleus, producing a particle and its antiparticle. This demonstrates the interchangeable nature of mass and energy.

5. What implications does the relationship between mass and energy have?

The relationship between mass and energy has significant implications in understanding the universe and how it functions. It helps explain phenomena such as the production of energy in stars, the behavior of particles in particle accelerators, and the creation of matter in the early universe.

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