I First Energy or Mass: Universe Origins

Pring
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At the very beginning of universe, the energy exist in advance of mass? Or mass exist in advance of energy? From the Einstein equation, E=mc2, energy is really equivalent to mass? I just see that people take energy from mass defect, but rarely hear that people take mass from energy.
 
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No, energy is not equivalent to mass. It would be more appropriate to call mass a type of energy, much like kinetic or potential energy. An object's mass is equivalent to its energy in its rest frame, i.e., its rest energy.
 
Pring said:
rarely hear that people take mass from energy.
You've never heard of pair production? Also, each proton-proton collision at the Large Hadron Collider produces many particles, each with mass that comes from the energies of the original protons.
 
Orodruin said:
No, energy is not equivalent to mass. It would be more appropriate to call mass a type of energy, much like kinetic or potential energy. An object's mass is equivalent to its energy in its rest frame, i.e., its rest energy.
In the moving frame, mass is equivalent to its moving energy?
 
jtbell said:
You've never heard of pair production? Also, each proton-proton collision at the Large Hadron Collider produces many particles, each with mass that comes from the energies of the original protons.
I can understand like that particles collisions produce energy, and the rest of them divide and transform to other particles.
 
Pring said:
particles collisions produce energy
In what sense? The total energy after the collision always equals the total energy before the collision, where "energy" includes the "rest-energy" a.k.a. "mass" of each particle existing at a given time.
 
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Pring said:
the energy exist in advance of mass? Or mass exist in advance of energy?

This is like asking if "left" exists before "up".
 
How high is up?
 
  • #10
jtbell said:
In what sense? The total energy after the collision always equals the total energy before the collision, where "energy" includes the "rest-energy" a.k.a. "mass" of each particle existing at a given time.
I know energy must be conserved. Mass of each particle, which exists at a given time, changes into energy. It is not a good example of energy transforming into mass. Do pure energy directly change into particles?
 
  • #12
Vanadium 50 said:
This is like asking if "left" exists before "up".
So first energy or mass?
 
  • #13
Pring said:
Do pure energy directly change into particles?
There is no such thing as "pure energy". Energy comes in many different form. Mass, or equivalently rest energy, is one such form.
 
  • #14
Orodruin said:
There is no such thing as "pure energy". Energy comes in many different form. Mass, or equivalently rest energy, is one such form.
Energy comes from material. Is there any experiment that the total rest mass increase after particles collisions?
 
  • #15
Orodruin said:
There is no such thing as "pure energy". Energy comes in many different form. Mass, or equivalently rest energy, is one such form.
Can I understand the photon, which has no mass, as pure energy? If I just treat it as an assumption, it would take me any problems?
 
  • #16
Pring said:
Can I understand the photon, which has no mass, as pure energy? If I just treat it as an assumption, it would take me any problems?
No. Again, there is no such thing as "pure energy". Energy is not even a Lorentz invariant.
 
  • #17
Orodruin said:
No. Again, there is no such thing as "pure energy". Energy is not even a Lorentz invariant.
OK. Thanks, I have understood that nothing is called pure energy but rest energy, potential energy... In addition, is there any experiment that the total rest mass increase after particles collisions? This case means that rest energy change into mass. Finally, mass is equivalent to rest energy, which is inertial structure. Thus, once mass appears, the rest energy just appears. But I still have one question, in the very beginning of universe, which energy should exist firstly? Rest energy is the first one?
 
  • #18
Pring said:
is there any experiment that the total rest mass increase after particles collisions?
If you are talking about adding up the individual rest masses before the collision and getting one figure, then adding up the individual rest masses after the collision and comparing then yes. That happens essentially every time particles are collided in an accelerator.
 
  • #19
jbriggs444 said:
If you are talking about adding up the individual rest masses before the collision and getting one figure, then adding up the individual rest masses after the collision and comparing then yes. That happens essentially every time particles are collided in an accelerator.
Thanks. At the very beginning of universe, first energy or mass?
 
  • #20
Pring said:
Thanks. At the very beginning of universe, first energy or mass?
You keep asking this question. Are you sure that it means what you think it means?

[With apologies to Inigo Montoya]
 
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  • #21
Pring said:
Thanks. At the very beginning of universe, first energy or mass?
Two photons going in opposite directions. Individually, neither has mass. Considered together they have mass. Which came first?

I don't think your question has an answer, any more than mine does. Mass and energy aren't entirely separate concepts, so talking about which one came first doesn't really make sense.
 
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  • #22
Mass and rest energy are the same thing, just expressed in different units. It might make things easier for you if you simply forget about "mass" altogether for a moment, and focus instead on energy:

The total energy ##E## of a closed system is a special quantity because it's conserved. That's why we care about it.

Now, a system's total energy is the sum of its rest energy ##E_0## and its kinetic energy ##E_k##:

##E = E_0 + E_k##.

You can see that when ##E_k = 0##, we have ##E = E_0##. So rest energy is just the total energy of a system as measured in its own rest frame.

Since mass and rest energy are fundamentally the same thing, your question can be rephrased: "Which came first: the total energy of a system, or the total energy of a system as measured in its rest frame?"

The question makes no sense.
 
  • #23
Ibix said:
Two photons going in opposite directions. Individually, neither has mass. Considered together they have mass. Which came first?

I don't think your question has an answer, any more than mine does. Mass and energy aren't entirely separate concepts, so talking about which one came first doesn't really make sense.

how are two photons considered together as having mass? There are lots of photons, I thought they're all massless? Should I not think of them together? :)

Does the calculated mass of a galaxy account for it's energies separately? The "momentum field" of light must be significant for a whole galaxy. Bah, we can frame it, it's all mass. :/
 
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  • #24
SiennaTheGr8 said:
Mass and rest energy are the same thing, just expressed in different units. It might make things easier for you if you simply forget about "mass" altogether for a moment, and focus instead on energy:

The total energy ##E## of a closed system is a special quantity because it's conserved. That's why we care about it.

Now, a system's total energy is the sum of its rest energy ##E_0## and its kinetic energy ##E_k##:

##E = E_0 + E_k##.

You can see that when ##E_k = 0##, we have ##E = E_0##. So rest energy is just the total energy of a system as measured in its own rest frame.

Since mass and rest energy are fundamentally the same thing, your question can be rephrased: "Which came first: the total energy of a system, or the total energy of a system as measured in its rest frame?"

The question makes no sense.

The perspective is impressive. We know photon has no rest energy, can I suppose that the universe is full of photon at the very beginning, and then generate rest energy?
 
  • #25
Pring said:
This case means that rest energy change into mass.

Rest energy and mass are two different names for the same thing. Asking which came first or if one can change into the other are questions devoid of meaning. What difference do you think an answer would make?
 
  • #26
nitsuj said:
how are two photons considered together as having mass?

Consider some frame in which two photons have equal but opposite momenta. Such a frame is a rest frame for the two photon system, so the total energy of the two photons equals the mass of the system.

What seems strange is that the sum of the masses of the constituents of the system is not equal to the mass of the system. But this is the essential lesson of the Einstein mass-energy equivalence.
 
  • #27
Mister T said:
Rest energy and mass are two different names for the same thing. Asking which came first or if one can change into the other are questions devoid of meaning. What difference do you think an answer would make?
Yeah, nothing different. Aha, I am so clumsy.
 
  • #28
Mister T said:
Consider some frame in which two photons have equal but opposite momenta. Such a frame is a rest frame for the two photon system, so the total energy of the two photons equals the mass of the system.

What seems strange is that the sum of the masses of the constituents of the system is not equal to the mass of the system. But this is the essential lesson of the Einstein mass-energy equivalence.
So single photon is less massive. But from the perspective of multi-photon system, we select the rest frame, and the total energy is equivalent to mass. If we have a sphere symmetry system in a box, which always appears pairs of photons with opposite momentum in all directions by lasers, the equivalent mass could be arbitrarily large. Furthermore, if we move the box, it is hard.
 
  • #29
Mister T said:
Consider some frame in which two photons have equal but opposite momenta. Such a frame is a rest frame for the two photon system, so the total energy of the two photons equals the mass of the system.

What seems strange is that the sum of the masses of the constituents of the system is not equal to the mass of the system. But this is the essential lesson of the Einstein mass-energy equivalence.
If I consider some frame in which two electrons have equal but opposite momenta. The total energy of the two electrons equals the mass of the system. So the system rest energy includes not only kinetic energy, but also their individual rest energy. Moreover, the potential is not considered for mass in any case. Finally, 'first energy or mass', the mass is equivalent to rest energy or system rest energy, and mass is just a perspective of rest frame. So energy always exists, and mass is just a perspective. Right?
 
  • #30
Pring said:
So the system rest energy includes not only kinetic energy, but also their individual rest energy.

Yes.

Pring said:
Moreover, the potential is not considered for mass in any case.

No. The potential energy due to the electrons repelling each other has to be included. Otherwise energy conservation won't hold, because the electrons repel each other and will therefore accelerate apart, increasing their kinetic energy--and if you don't include potential energy, it will seem like the system's total energy is increasing, not conserved.
 
  • #31
PeterDonis said:
it will seem like the system's total energy is increasing, not conserved.
Yeah, you are right!
 
  • #32
Pring said:
Moreover, the potential is not considered for mass in any case.

The rest energy (mass) of a system includes the potential energy of the system. Note that the total energy is the sum of the rest energy and the kinetic energy. Potential energy doesn't appear explicitly in that sum because it's already included in the rest energy.
 
  • #33
Mister T said:
Potential energy doesn't appear explicitly in that sum because it's already included in the rest energy.

No, it isn't--at least, not the way @Pring was looking at the system. If you view the system as two electrons interacting, then the total energy, in the system's rest frame (i.e., the center of mass frame), has three components: the rest energy of the two electrons, the kinetic energy of the two electrons, and the potential energy of the interaction between them. The potential energy can't be assigned to either electron alone, so it can't be counted as part of the rest energy of either electron.

If you view the system from the outside, then yes, the potential energy between its parts, if any, is counted as part of the system's rest energy. But @Pring wasn't talking about that case; he was talking about just the system of the two electrons, viewed in its own rest frame (so the kinetic energy of the system as a whole is zero).
 
  • #34
Pring said:
So single photon is less massive. But from the perspective of multi-photon system, we select the rest frame, and the total energy is equivalent to mass. If we have a sphere symmetry system in a box, which always appears pairs of photons with opposite momentum in all directions by lasers, the equivalent mass could be arbitrarily large. Furthermore, if we move the box, it is hard.
Does this case be black hole?
 
  • #35
Hi.
Pring said:
At the very beginning of universe, the energy exist in advance of mass? Or mass exist in advance of energy?

My intuition is energy and mass are two different names for the same phenomenon.

Although single photon, that has no rest frame, has no mass but energy, photon gas, that has its rest frame in the sense of zero total momentum, has both mass and energy. I am not sure at all that at the very beginning of universe there is only ONE photon or particle of speed c. Best.
 
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  • #36
sweet springs said:
Hi.My intuitive is energy and mass are two different names for the same phenomenon.

Although single photon that has no rest frame has no mass but energy, photon gas that has its rest frame in the sense of zero total momentum has both mass and energy.
Yeah, we discuss mass meaningful in rest frame. There are some differences in individual and systematic cases. Mass is equivalent to rest energy, and include all the necessary energy in the rest frame. So I think mass or rest energy is a perspective or concept to express the rest energy state. At the very beginning of universe, energy of other particles always exists when you stand on some particle reference system (if you stand on some photon reference system, own energy is 0), and nothing would exist independently. So from the system view, in the rest frame, rest energy always exists, which is just another landscape of energy by different reference system.
 
  • #37
nitsuj said:
how are two photons considered together as having mass? There are lots of photons, I thought they're all massless? Should I not think of them together? :)

Does the calculated mass of a galaxy account for it's energies separately? The "momentum field" of light must be significant for a whole galaxy. Bah, we can frame it, it's all mass. :/
An individual photon has energy ##E=h\nu## and momentum ##p=h\nu/c##. That makes its mass ##m^2c^4=E^2-p^2c^2=0##. Two photons traveling in opposite directions have total energy ##E=h\nu+h\nu=2h\nu## and total momentum ##p=h\nu/c+(-h\nu/c)=0##. So their total mass is non-zero.

What this means is that if you have a box full of photons then their energy contributes to its mass so, for example, you won't detect a mass change from someone in a sealed box turning on a light. So yes, I think the mass of light in flight will technically be taken into account when measuring the mass of a galaxy. Since galaxies are a few thousands of light years across and stars last billions of years, converting only a tiny fraction of their mass to radiation, I expect it's pretty much totally negligible.
 
  • #38
Pring said:
At the very beginning of universe, first energy or mass?
Hi Pring:

I am getting the impression that the very knowledgeable respondents have not yet understood what you are trying to ask. I am not an expert but I think I have a feel for your question, so I will try to make a helpful answer.

You want to understand the earliest state of the universe in terms of the matter and/or energy present at that time. My answer is that it consisted of a lot of particles. Far the most common kind of particles were photons. You might want to ask, "Is a photon a constituent of matter?"
The following presents several views about this.
The last sentence of one answer is:
Consequently, photons are probably not matter, and they are definitely not energy.​
Another answer ends with:
So, no, photons are not matter.​
I may be wrong, but I think it reasonable to also say that a photon is a non-matter particle that is the carrier of electromagnetic energy (EM). It is not itself the energy, but it carries energy.

In addition to the photons, the earliest universe also consists of every type of fundamental particle that can exist. By fundamental, I mean that each of these particles does not consist of any combination of smaller particles. The mass equivalent of the average EM energy carried by a photon during this period is greater than than the largest mass of any of the other particles. This environment involves constant changes of primarily two kinds:
1. Two photons will collide with each other, and each collision will produce a pair of some other kind of particle: (a) matter particles, i.e. particles with mass; (b) particles without mass that are carriers of some other form of energy than EM, e.g. gluons. The pair will be the anti-particles of each other.
2. A particle and its anti-particle will collide and destroy each other with all of their combined energy being converted to photons.
(Other kinds of collision changes will also occur, but that complexity is not relevant to your question.)

I think the most reasonable way to describe this early universe environment with respect to matter and energy is that the universe contained both matter and energy. It never consisted of only one or the other.

I hope this is helpful to you.

Regards,
Buzz
 
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  • #39
Buzz Bloom said:
I think the most reasonable way to describe this early universe environment with respect to matter and energy is that the universe contained both matter and energy. It never consisted of only one or the other.
That's really helpful from the point of annihilation reaction in the early universe. I have concluded that
(i) Energy always exists in the front and back through annihilation reaction because of energy conservation;
(ii) Mass is equivalent to rest energy, and is a special case of energy in the rest frame. Thus, mass always exists for the whole system. Noted that if we assume universe just consist of photons, and they go in the same directions so they can't react to generate particles, this case has no mass. But we know the universe isotropic principle which makes these photons as a whole in the rest frame just have mass, let alone consider particles;
(iii) Original question is non-sense. Another question is that 'first rest energy or other energy'. What is the essential difference between rest energy and other energy such as kinetic energy? If we couldn't find any essential difference, we just can't find out which energy is first. In addition, if we stand on the view of whole universe, I think I just assume the initial universe is static which means that universe don't have move energy like kinetic energy, so it is itself rest frame, and has non-zero rest energy based on (ii). If the big bang theory is right, with the help of God to light, the universe expand. In this case, the rest frame of the whole universe is the soaring center. The global rest energy just conserved, but in the local area, the rest energy should transform into other energies because the local mass center just move far away from the center. So the rest energy is first in my consideration based on the static assumption.
 
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  • #40
Buzz Bloom said:
You want to understand the earliest state of the universe in terms of the matter and/or energy present at that time.

Which means that first you need to define what you mean by "matter" and "energy". (Also, the OP did not say "matter"; he said "mass". They're not the same.)

Buzz Bloom said:
The following presents several views about this.

No, it presents several different definitions of terms. Which means the "views" expressed are not about physics but about terminology.

Buzz Bloom said:
I think it reasonable to also say that a photon is a non-matter particle that is the carrier of electromagnetic energy (EM).

This is reasonable, but it is also reasonable when talking about the early universe to ignore the matter/non-matter distinction altogether and just talk about the various particles and their properties. This is particularly relevant in the early universe since the key distinction that makes cosmologists adopt the term "matter" only for certain particles in the present universe--the fact that "matter" is cold (i.e., its kinetic energy is negligible compared to its rest energy)--is not present in the early universe (see below).

Buzz Bloom said:
The mass equivalent of the average EM energy carried by a photon during this period is greater than than the largest mass of any of the other particles.

The way you are stating this is misleading. A better statement would be that the average temperature of the universe (which means the average energy of everything, not just photons) was much larger than the rest mass of any of the particles. Which means all of the particles can be treated as highly relativistic and their rest masses can be ignored in most calculations. (Even this glosses over some important issues like the electroweak phase transition.)

Buzz Bloom said:
I think the most reasonable way to describe this early universe environment with respect to matter and energy is that the universe contained both matter and energy. It never consisted of only one or the other.

I think it's even more reasonable to just say the early universe contained a lot of relativistic particles, all of which carried energy, without even bothering about the matter/non-matter distinction. See above.
 
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  • #41
Pring said:
Energy always exists in the front and back through annihilation reaction because of energy conservation

You can take out the "through annihilation reaction" part--energy is conserved in all processes, not just those particular ones. In other words, "energy always exists because energy is conserved".

Pring said:
Mass is equivalent to rest energy, and is a special case of energy in the rest frame. Thus, mass always exists for the whole system.

This works for local processes, but it doesn't work for the whole universe, because the whole universe does not have a "rest frame" in the sense you are using the term here. (Also, since our best current model says the universe is spatially infinite, it doesn't have a well-defined total mass/energy. The best you can do is to define an energy density, or more generally a stress-energy tensor.)

Pring said:
Another question is that 'first rest energy or other energy'.

This question is meaningless, because, as noted above, the whole universe does not have a "rest frame".

Pring said:
I think I just assume the initial universe is static

This is wrong. The early universe was expanding rapidly.

Please also bear in mind the PF rules on personal speculation.
 
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  • #42
The OP question has been answered. Thread closed.
 
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