Why is the Speed of Light Squared in E=mc^2?

In summary: I would like to have a pratical "image" (a pratical experience) of this."In summary, the famous equation e=mc^2 has practical applications in physics and is a hallmark of a good theory. The units of speed squared, m^2/s^2, may not have a direct physical significance, but the crucial point is that (1/2)mv^2 and mc^2 have units of energy. A practical experience to understand this concept could involve reaching the speed of light, but it is not possible to reach this speed due to the "obstacle" of the squared speed of light, c^2."
  • #36
Entropy said:
Yes it is.

NO, it isn't. Because to Einstein, realtivistic mass and energy are simply two different names for one and the same physical quantity. Read Einstein carefully and you will verify that this is as Iam saying.

Entropy said:
Millions of experiments have proven this. Just about every experiment ever to involve particle accelerators involves Einstien's equations.

Humm. The formula has been partially proven. But I am talking from the beginning about a total proof.
 
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  • #37
Swampeast Mike said:
In this context "deception" would mean pretending to be a different coalescence of mass in the universe.

Your question is universal as is my attempted explanation of a universe where time and space are relative. It is not however, and I repeat NOT, based upon faith.

If you call "Faith" to the will of discover the truth freely without blarney anybody, YES is faith what determines my study, faith of getting the truth. The faith that you are talking about, you only could deduce it from my words with a great faith.
 
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  • #38
free_mind said:
Humm. The formula has been partially proven. But I am talking from the beginning about a total proof.
There isn't total proof in science. But the equivalence of matter and energy is as close to completely proven as anything in science ever gets.
 
  • #39
russ_watters said:
There isn't total proof in science. But the equivalence of matter and energy is as close to completely proven as anything in science ever gets.

Don't interpret my words literally, they are not a mathematic formula :) . In science nor in nothing you have 100% . But show me an example where the E=mc^2 formula has been completely (not parcially and not because has been important to get conclusions in other observations, etc) proved.
 
  • #40
free_mind said:
Don't interpret my words literally, they are not a mathematic formula :) . In science nor in nothing you have 100% . But show me an example where the E=mc^2 formula has been completely (not parcially and not because has been important to get conclusions in other observations, etc) proved.

Didn't someone already point that out to you a few times already? Big flash of light... mushroom cloud...
 
  • #41
Doc Al said:
Yes! Even in chemical reactions [itex]E = m c^2[/itex] applies. Of course the amount of rest mass "converted" to energy is much less in chemical reactions than in nuclear reactions.


What are you talking about? [itex]E = m c^2[/itex] is a result derived from Special Relativity, which has been exhaustively tested. Nuclear reactions, controlled or otherwise, have directly confirmed [itex]E = m c^2[/itex].


Again, what are you talking about? We've given several examples. You've even supplied one. (What do you mean by a "practical" sense?)

Until now I saw examples of parcial pratical application of the formula E=mc^2 .
 
  • #42
Pengwuino said:
Didn't someone already point that out to you a few times already? Big flash of light... mushroom cloud...

Study the Einstein theory and you will find that Einstein's politics played a more decisive role in the story of the atomic bomb than his physics.
 
  • #43
free_mind said:
Study the Einstein theory and you will find that Einstein's politics played a more decisive role in the story of the atomic bomb than his physics.

... Someones political feelings does not change the laws of physics. E=mc^2 was fully demonstrated by the atomic bomb. How exactly can you dispute that? What is the "part" that is explained that isn't the whole of the theory?
 
  • #44
free_mind said:
Study the Einstein theory and you will find that Einstein's politics played a more decisive role in the story of the atomic bomb than his physics.
Why not study Einstein's theory to find out how [itex]E = m c^2[/itex] is derived and what it means? :wink:
 
  • #45
Pengwuino said:
... Someones political feelings does not change the laws of physics. E=mc^2 was fully demonstrated by the atomic bomb. How exactly can you dispute that? What is the "part" that is explained that isn't the whole of the theory?

Ok. I will try to be synthetic taking in account the place where we are.

The strength of the nuclear bond depends on the number of neutrons and protons involved. It varies in such a way that binding energy is released both in splitting up a heavy nucleus into smaller parts and in fusing light nuclei into heavier ones. This, as well as the chain reaction phenomenon, explains the immense power of nuclear bombs.

Einstein's formula it's all about different kinds of energy. Sure, there are some radioactive decay processes following nuclear fission, and, if so inclined, one can view the decay of a neutron decaying into a slightly lighter proton as a transformation of rest energy into other energy forms. But these additional processes contribute a mere 10 per cent of the total energy set free in nuclear fission. The main contribution is due to binding energy being converted to other forms of energy - a consequence not of Einstein's formula, but of the fact that nuclear forces are comparatively strong, and that certain lighter nuclei are much more strongly bound than certain more massive nuclei.
 
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  • #46
Doc Al said:
Why not study Einstein's theory to find out how [itex]E = m c^2[/itex] is derived and what it means? :wink:

The mathematic meaning could be far from the pratical world. Don't you know many situations in which this happens?

Mathematics couldn't be seen as an absolute concept to explain the world, notwithstanding the enormous help that gave and will give in our understanding of the world .
 
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  • #47
free_mind said:
NO, it isn't. Because to Einstein, realtivistic mass and energy are simply two different names for one and the same physical quantity. Read Einstein carefully and you will verify that this is as Iam saying.

It is true that for single point particles, relativistic mass and energy are the same. It's also true that nuclear reactions transform matter into energy. I don't see why you are advancing the first point as a counter-argument to the second - both are true.
 
  • #48
pervect said:
It is true that for single point particles, relativistic mass and energy are the same. It's also true that nuclear reactions transform matter into energy. I don't see why you are advancing the first point as a counter-argument to the second - both are true.

Einstein would say that in a system where there is energy (E), it automatically has the relativistic mass m=E/c2; whenever a system has the mass m, you need to assign it an energy E=mc2. Once the mass is known, so is the energy, and vice versa. In that context, it makes no sense to talk about the "transformation of mass into energy" - where there's one, there's the other.
 
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  • #49
free_mind said:
Einstein would say that in system where there is energy (E), it automatically has the relativistic mass m=E/c2; whenever a system has the mass m, you need to assign it an energy E=mc2. Once the mass is known, so is the energy, and vice versa. In that context, it makes no sense to talk about the "transformation of mass into energy" - where there's one, there's the other.

Some energy you can do work with. But a mass just sitting at rest (you do know the formula [tex]e=mc^2[/tex] is only true in the rest frame don't you?) can't do any work. In order to transform the frozen form of energy we call matter into the fluid kind that can do work we need some specific physical transformation to take place.
 
  • #50
free_mind said:
The mathematic meaning could be far from the pratical world. Don't you know many situations in which this happens?
Name one relevant to this thread.
 
  • #51
free_mind said:
Einstein's formula it's all about different kinds of energy. Sure, there are some radioactive decay processes following nuclear fission, and, if so inclined, one can view the decay of a neutron decaying into a slightly lighter proton as a transformation of rest energy into other energy forms. But these additional processes contribute a mere 10 per cent of the total energy set free in nuclear fission. The main contribution is due to binding energy being converted to other forms of energy - a consequence not of Einstein's formula, but of the fact that nuclear forces are comparatively strong, and that certain lighter nuclei are much more strongly bound than certain more massive nuclei.

There is no difference in the basic principle regardless of what part of the atom it comes from, and I believe you know that already. Einstein's formula still applies and is calculated exactly the same way.

So my question is, what are you really asking here in this forum? Are you trying to get the answer to a question (somehow I am beginning to doubt this) or are you trying to make a specific statement? If you are trying to make a statement, perhaps you could move forward to that.
 
  • #52
Frankly, the critical units error in the opening post seems to be the whole point of the thread - but even after it was pointed out, free_mind doesn't seem to want to drop the line of reasoning that error started. free_mind appears to not want to let go of the idea that c^2 is a speed.
 
  • #53
russ_watters said:
Name one relevant to this thread.

Generically speaking the difference between pure mathematics and applied mathematics. I know that there are several cases where pure mathematics became applied mathematics. But I am not so optimistic as Nikolai Lobachevsky: "There is no branch of mathematics, however abstract, which may not someday be applied to the phenomena of the real world."
 
  • #54
selfAdjoint said:
Some energy you can do work with. But a mass just sitting at rest (you do know the formula [tex]e=mc^2[/tex] is only true in the rest frame don't you?) can't do any work. In order to transform the frozen form of energy we call matter into the fluid kind that can do work we need some specific physical transformation to take place.

The specific physical transformation results from the other forms of energy. The main energy set free in a nuclear fission results from binding energy converted to other forms of energy.
 
  • #55
DrChinese said:
There is no difference in the basic principle regardless of what part of the atom it comes from, and I believe you know that already. Einstein's formula still applies and is calculated exactly the same way.

So my question is, what are you really asking here in this forum? Are you trying to get the answer to a question (somehow I am beginning to doubt this) or are you trying to make a specific statement? If you are trying to make a statement, perhaps you could move forward to that.

The scope that underlies my participation in this forum, is mainly related with the difficulty in define the exact characterization of c^2 and it's qualitative meaning, on the other hand, the inexistence of an empirical demonstration where the Einstein formula has been completely proven.

HallsofIvy about c^2 said: "No one has said that "speed squared" has any particular physical significance. You can if you like think of it as J/kg (...)". Where in this affirmation is the scientific precision?
 
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  • #56
The main energy set free in a nuclear fission results from binding energy converted to other forms of energy.

The binding energy adds to the atom's mass. Why do you think a He-4 nucleus doesn't have the same mass as two protons and two neutrons?
 
  • #57
Entropy said:
The binding energy adds to the atom's mass. Why do you think a He-4 nucleus doesn't have the same mass as two protons and two neutrons?

Please, read the thread #45.
 
  • #58
Please, read the thread #45.

I did. You don't understand. Binding energy contributes to an atom's mass. Two protons and two neutrons have a smaller mass than a He-4 nucleus. If you don't believe me, look up the masses of [free] two protons and [free] two neutrons and compare it to the mass of a He-4 nucleus. That change in mass is because when these 4 nucleons join to form a single nucleus, known as nuclear fusion, mass from these nucleons is converted directed into energy. The change in mass when plugged into E = mc^2 will yield the exact energy released in the TOTAL reaction. That proves the equation is right. (Note: a more common form of neclear fusion involves H-2 and two protons, which happens in the sun, but it is more complex because it results in the production of positions and this other is reaction is simplier and works for these purposes).
 
  • #59
free_mind said:
The scope that underlies my participation in this forum, is mainly related with the difficulty in define the exact characterization of c^2 and it's qualitative meaning, on the other hand, the inexistence of an empirical demonstration where the Einstein formula has been completely proven.

HallsofIvy about c^2 said: "No one has said that "speed squared" has any particular physical significance. You can if you like think of it as J/kg (...)". Where in this affirmation is the scientific precision?

There isn't any particular difficulty in the characterization of c^2 and it's meaning. The only difficulty is in your understanding.

We've given you a very simple analogy - a foot is different than a foot^2.

For more advanced understanding, we've given you links to the theory of dimensional analysis, which addresses the topic of whether c is different than c^2 more precesisly than the simple, easy-to-understand analogy does or can.

The analogy alone should be enough to at least make you think about why you assume that c is equivalent to c^2. Given that a foot is not equivalent to a foot^2, why should you asusme that a velocity (c) is equivalent to a velocity^2 (c^2)?

The one thing we haven't done (yet) is to spoon-feed you some of the elements of dimensional analysis. I'll try that in a bit, but I do get the feeling that you aren't really hear to learn stuff, you don't seem to be listening very much. Rather than listening, you seem to be making a bunch of more or less unfounded statements, and then attempting to defend them. Anything that doesn't agree with your unfounded claims seems to get mostly ignored.

Before I start, I'm going to ramble on a bit about the role of mathematics in physics. Mathematics is not a hinderance, as you seem to think. It is an esesential tool. Mathematics does not cause errors in understanding. Mathematics greatly helps to eliminate errors. It *is* possible for errors to creep in in spite of mathematics. This happens when one makes incorrect assumptions. Mathematics is a codified form of logic, so it helps to insure that the conclusiosn follow from the premises. It can't necessarily find errors in the fundamental assumptions. It can greatly aid in ensuring that the conclusions follow from the premises.

Enough about mathematics, let's go back to spoon-feeding you some dimensional analysis.

The idea of dimensional analysis is that every phhysical quantity contains two parts: a number, which gives the magnitude of the quantity, and a unit, which describes how the quantity transforms under scale changes.

Scale changes are when one uses different units - like feet, instead of inches, or seconds instead of minutes.

So let's go back to feet and feet^2. There are 12 inches in a foot, so the rules of dimensional analysis tell us that if we have one foot, and we transform it so that it's units are in inches, we get 12 inches. These two expressions represent the same physical quantity, i.e. 1 foot is 12 inches.

The same rules tell us that if we have one square foot, when we transform to inches we get 144 square inches.

You can check this out for yourself if you really want to - take a square foot, and see how many square inches are in it.

Note that the rules of transformation are totally different for square feet than they are for feet.

This is why we say that feet^2 are different than feet. It also means that we can't directly compare quantites in feet and quantities in square feet in any meaningful way. Because the quanties transform differently, the result of comparing the number part of the quantites will not give the same result in different units (remember, every physical quantity has two parts - a number, and a unit).

These rules can be written down very concisely by treating units as quantites which 'cancel out' in fractions.

See for instance

http://www.chemistrycoach.com/use.htm

[tex]
1\, foot * \frac{12\, inches}{1\, foot} = 12 inches
[/tex]

Feet appear in the numerator and denominator once, and "cancel out", leaving inches.

[tex]
1\, foot^2 *\left( \frac{12\, inches}{1\, foot} \right)*\left( \frac{12\, inches}{1\, foot}\right) = 144 inches^2
[/tex]

Feet appear twice in the numerator and denominator. Both feet "cancel out", leaving inches^2.

Now, let's apply this to velocity.

Suppose we have a velocity of 1 foot/second. The rules of dimensional analysis say that this transforms to 12 inches/second.

Now let's say we have a velocity^2 of 1 foot^2 / second^2. The rules of dimensional anaysis say that this transforms to 144 inches^2/second^2.

Now you can see why a velocity^2 is different than a velocity. The numerical value transforms in a completely different manner when we change units (i.e feet to inches, in this example).

We can also use dimensional analysis to transform the seconds into minutes

60 feet/minute == 1 foot/second
3600 feet^2/minute^2 = 1 foot^2/second^2.

Knowing how to transform both the "feet" (distance), and the "seconds" (time) in the velocity gives us all the information we need to transform a velocity from feet/seconds to any other units we desire. (Furlongs per fortnight, for an extreme example).

This is dimensional analysis in a nutshell. To recap, a physical quantity consists of two parts: a number, AND a unit. Two quantites can be compared directly only if they have the same units. c and c^2 do not have the same units, so they cannot be compared dirrectly.
 
  • #60
free_mind said:
Generically speaking the difference between pure mathematics and applied mathematics. I know that there are several cases where pure mathematics became applied mathematics.
Not good enough. You say its a general principle, then say you have a specific example: give us your specific example, or admit you have none.

You're claiming that SR is wrong because it hasn't been "completely" proven. Don't you see the contradiction there?

And again, free_mind - doesn't your error in your first post concern you?

edit: So in your first post, you demonstrated that you don't understand the math of units, and in further posts, you demostrated that you don't understand the scientific method (the invalidity of the concept of "completely proven"). With such severe misunderstandings out in the open (you seem to have acknowledged the first, at the very least), don't you think you should take a step back and consider the validity of your opinion?
 
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  • #61
pervect said:
There isn't any particular difficulty in the characterization of c^2 and it's meaning. The only difficulty is in your understanding.

We've given you a very simple analogy - a foot is different than a foot^2.

For more advanced understanding, we've given you links to the theory of dimensional analysis, which addresses the topic of whether c is different than c^2 more precesisly than the simple, easy-to-understand analogy does or can.

The analogy alone should be enough to at least make you think about why you assume that c is equivalent to c^2. Given that a foot is not equivalent to a foot^2, why should you asusme that a velocity (c) is equivalent to a velocity^2 (c^2)?

The one thing we haven't done (yet) is to spoon-feed you some of the elements of dimensional analysis. I'll try that in a bit, but I do get the feeling that you aren't really hear to learn stuff, you don't seem to be listening very much. Rather than listening, you seem to be making a bunch of more or less unfounded statements, and then attempting to defend them. Anything that doesn't agree with your unfounded claims seems to get mostly ignored.

Before I start, I'm going to ramble on a bit about the role of mathematics in physics. Mathematics is not a hinderance, as you seem to think. It is an esesential tool. Mathematics does not cause errors in understanding. Mathematics greatly helps to eliminate errors. It *is* possible for errors to creep in in spite of mathematics. This happens when one makes incorrect assumptions. Mathematics is a codified form of logic, so it helps to insure that the conclusiosn follow from the premises. It can't necessarily find errors in the fundamental assumptions. It can greatly aid in ensuring that the conclusions follow from the premises.

Enough about mathematics, let's go back to spoon-feeding you some dimensional analysis.

The idea of dimensional analysis is that every phhysical quantity contains two parts: a number, which gives the magnitude of the quantity, and a unit, which describes how the quantity transforms under scale changes.

Scale changes are when one uses different units - like feet, instead of inches, or seconds instead of minutes.

So let's go back to feet and feet^2. There are 12 inches in a foot, so the rules of dimensional analysis tell us that if we have one foot, and we transform it so that it's units are in inches, we get 12 inches. These two expressions represent the same physical quantity, i.e. 1 foot is 12 inches.

The same rules tell us that if we have one square foot, when we transform to inches we get 144 square inches.

You can check this out for yourself if you really want to - take a square foot, and see how many square inches are in it.

Note that the rules of transformation are totally different for square feet than they are for feet.

This is why we say that feet^2 are different than feet. It also means that we can't directly compare quantites in feet and quantities in square feet in any meaningful way. Because the quanties transform differently, the result of comparing the number part of the quantites will not give the same result in different units (remember, every physical quantity has two parts - a number, and a unit).

These rules can be written down very concisely by treating units as quantites which 'cancel out' in fractions.

See for instance

http://www.chemistrycoach.com/use.htm

[tex]
1\, foot * \frac{12\, inches}{1\, foot} = 12 inches
[/tex]

Feet appear in the numerator and denominator once, and "cancel out", leaving inches.

[tex]
1\, foot^2 *\left( \frac{12\, inches}{1\, foot} \right)*\left( \frac{12\, inches}{1\, foot}\right) = 144 inches^2
[/tex]

Feet appear twice in the numerator and denominator. Both feet "cancel out", leaving inches^2.

Now, let's apply this to velocity.

Suppose we have a velocity of 1 foot/second. The rules of dimensional analysis say that this transforms to 12 inches/second.

Now let's say we have a velocity^2 of 1 foot^2 / second^2. The rules of dimensional anaysis say that this transforms to 144 inches^2/second^2.

Now you can see why a velocity^2 is different than a velocity. The numerical value transforms in a completely different manner when we change units (i.e feet to inches, in this example).

We can also use dimensional analysis to transform the seconds into minutes

60 feet/minute == 1 foot/second
3600 feet^2/minute^2 = 1 foot^2/second^2.

Knowing how to transform both the "feet" (distance), and the "seconds" (time) in the velocity gives us all the information we need to transform a velocity from feet/seconds to any other units we desire. (Furlongs per fortnight, for an extreme example).

This is dimensional analysis in a nutshell. To recap, a physical quantity consists of two parts: a number, AND a unit. Two quantites can be compared directly only if they have the same units. c and c^2 do not have the same units, so they cannot be compared dirrectly.

Thank you for you exposition. But where do you get the idea that I considered that c is equal to c^2?

The problem is that 89875517873681764 m^2/s^2 have to be verified in a concrete experience. I don't know any experience where this have been verified. It is always said that the formula contributed to...; has been important to...; and so on... Entropy said in thread #31: "Millions of experiments have proven this. Just about every experiment ever to involve particle accelerators involves Einstien's equations." This means that 89875517873681764 m^2/s^2 has been achieved in terms that has been clearly verified?

In SI units you don't find m^2/s^2. How can we interpret this?
HallsofIvy said that (thread #12): "(...) mc2 have units of energy- that has physical significance (...)". Units of energy? What's this? The Energy results from m.c^2. not from c^2.
 
  • #62
free_mind said:
In SI units you don't find m^2/s^2. How can we interpret this?
HallsofIvy said that (thread #12): "(...) mc2 have units of energy- that has physical significance (...)". Units of energy? What's this? The Energy results from m.c^2. not from c^2.

You will never find a m^2/s^2 as a real value. You must add hte mass to get kg * m^2/s^2 which is energy. C^2 needs no interpretation because there is no such thing as a square meter per squared second. Its simply a value that needs a mass to go with it before it has any physical meaning
 
  • #63
free_mind said:
Thank you for you exposition. But where do you get the idea that I considered that c is equal to c^2?
You quoted quite a long section. Didn't you bother to read it first? No one said you thought "c is equal to c^2". The word used was "equivalent"- you were comparing c^2 to a speed, c. They are different in the same sense that an area ("square feet") is completely different from a length ("feet")

The problem is that 89875517873681764 m^2/s^2 have to be verified in a concrete experience. I don't know any experience where this have been verified. It is always said that the formula contributed to...; has been important to...; and so on... Entropy said in thread #31: "Millions of experiments have proven this. Just about every experiment ever to involve particle accelerators involves Einstien's equations." This means that 89875517873681764 m^2/s^2 has been achieved in terms that has been clearly verified?
E= mc2 has been verified repeatedly. That says nothing about "89875517873681764 m^2/s^2 has been achieved". Since there is no physical quantity that has units of m^2/s^2, I don't even know what you mean by "achieved".

In SI units you don't find m^2/s^2. How can we interpret this?
HallsofIvy said that (thread #12): "(...) mc2 have units of energy- that has physical significance (...)". Units of energy? What's this? The Energy results from m.c^2. not from c^2.
Yes, read your own quote here: I said mc^2, not c^2! Once again, there is no physical quantity that has units of m^2/c^2.
 
  • #64
free_mind said:
The problem is that 89875517873681764 m^2/s^2 have to be verified in a concrete experience. I don't know any experience where this have been verified...

In SI units you don't find m^2/s^2. How can we interpret this?
HallsofIvy said that (thread #12): "(...) mc2 have units of energy- that has physical significance (...)". Units of energy? What's this? The Energy results from m.c^2. not from c^2.
The formula for the area of a circle is pi*r^2. So what does the r^2 on its own give us? Nothing! You can't take part of an equation and expect that part to have a physical meaning all its own. That simply isn't how math/science works.

Again, doesn't the error in your opening post cause you any concern about your line of reasoning?
 
  • #65
r squared?!? what an atrocity!
 
  • #66
free_mind said:
Einstein would say that in a system where there is energy (E), it automatically has the relativistic mass m=E/c2; whenever a system has the mass m, you need to assign it an energy E=mc2. Once the mass is known, so is the energy, and vice versa. In that context, it makes no sense to talk about the "transformation of mass into energy" - where there's one, there's the other.

An atomic nucleus has the same energy (relativistic mass) before and after it fissions. However, they are not physically the same, they do not represent the same state of matter. They have the same energy, but they are not otherwise equivalent.

Having the same energy is different from being identical. So E=mc^2 is a conservation law, not a statement that matter and energy are identical.
 
  • #67
free_mind said:
Thank you for you exposition. But where do you get the idea that I considered that c is equal to c^2?

Go back to the origin of the thread, where you write

e=mc^2 is equivalent to e=m.89875517873681764 m/s
The speed of light is a constant. How this is possible in reality?

Is not possible to have a body traveling at this speed, because simply doesn't exists (or at least we don't discover it yet).

I already read several answers to this kind of question. But the answers are around the intrinsic mathematical need to square c in the formula e=mc^2. I am looking for a logical reason for this problem, because beyond mathematical reasoning there are the reality; many times the mathematic coincides with reality, but in this problem, is what it happens?

I look for help to eliminate my difficulty in understanding this. Thank you.

At this point, you are confusing c^2, which is velocity squared, with 'c', which is a velocity. You appeared at this point to be actually asking a question, rather than sitting on a soapbox, orating, which seems to be your current conversational "posture".

Dimensional analysis is the answer to your original question at the start of the thread. c^2 is not a speed, and should not be compared to a speed.

Hurkyl has also pointed out other instances of this sort of invalid comparison.

BTW, confusing c^2 with a velocity is a reasonably common mistake (not the most common, but it happens a fair amount). Probably the most famous instance was in a very old science fiction story called "Venus Equilateral" by George O Smith. It reputedly took a lot of convicing (in the letter columns of a magizine, this was in the days before the internet, and before my time ), but eventually George learned something from the exchange, and stopped calling c^2 a velocity.

I can only hope that similar learning will occur in this thread, too.

Anyway, I think I've said what I need to say to anyone who is listening, I think I'm going to take a short vacation from this thread, there are plenty of other interesting questions out there, it feels like I'm beating a dead horse more than engaging in a conversation at this point.
 
  • #68
HallsofIvy said:
You quoted quite a long section. Didn't you bother to read it first? No one said you thought "c is equal to c^2". The word used was "equivalent"- you were comparing c^2 to a speed, c. They are different in the same sense that an area ("square feet") is completely different from a length ("feet")

That happened at my first thread. But why are you fixing your focus on that, taking in consideration that you can see in all my threads from that point that my positions didn't have nothing to do with the difference between m/s and m^2/s^2?

After all, until now, no one explain the meaning of m^2/s^2!

HallsofIvy said:
E= mc2 has been verified repeatedly. That says nothing about "89875517873681764 m^2/s^2 has been achieved". Since there is no physical quantity that has units of m^2/s^2, I don't even know what you mean by "achieved".")

C^2 is only a conversion factor with no particular meaning, that has resulted from mathematic deduction. This is what all accept!

HallsofIvy said:
Yes, read your own quote here: I said mc^2, not c^2! Once again, there is no physical quantity that has units of m^2/c^2.

Sorry, you are right, was a mistake. But the units problem persists. I suppose that in you satement you want to said m^2/s^2 and not m^2/c^2, right? :)
 
  • #69
pervect said:
Go back to the origin of the thread, where you write



At this point, you are confusing c^2, which is velocity squared, with 'c', which is a velocity. You appeared at this point to be actually asking a question, rather than sitting on a soapbox, orating, which seems to be your current conversational "posture".

About my posture you are wrong.

pervect said:
Dimensional analysis is the answer to your original question at the start of the thread. c^2 is not a speed, and should not be compared to a speed.

Hurkyl has also pointed out other instances of this sort of invalid comparison.

BTW, confusing c^2 with a velocity is a reasonably common mistake (not the most common, but it happens a fair amount). Probably the most famous instance was in a very old science fiction story called "Venus Equilateral" by George O Smith. It reputedly took a lot of convicing (in the letter columns of a magizine, this was in the days before the internet, and before my time ), but eventually George learned something from the exchange, and stopped calling c^2 a velocity.

I can only hope that similar learning will occur in this thread, too.

I am always searching for something to learn. My principle is: we can learn so much with the ones that don't know nothing.

pervect said:
Anyway, I think I've said what I need to say to anyone who is listening, I think I'm going to take a short vacation from this thread, there are plenty of other interesting questions out there, it feels like I'm beating a dead horse more than engaging in a conversation at this point.
I knew that m.m/s.s is equivalent to m^2/s^2, this is basic! But even if I had written correctly my doubt about velocity will be underlying my question. But you can see that no one in this forum characterized m^2/s^2. So, this units are something that no one knows what it is! :)

About your another comment, I am not going to say nothing, because you will beat me in experience. :)
 
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  • #70
russ_watters said:
The formula for the area of a circle is pi*r^2. So what does the r^2 on its own give us? Nothing! You can't take part of an equation and expect that part to have a physical meaning all its own. That simply isn't how math/science works.

Again, doesn't the error in your opening post cause you any concern about your line of reasoning?
r^2 is geometrically explainable, but c^2 with it's extraordinary units it's not so easy to explain.
 
<h2>1. Why is the speed of light squared in E=mc^2?</h2><p>The speed of light squared, or c^2, is included in the famous equation E=mc^2 because it represents the conversion factor between mass and energy. This means that mass and energy are essentially interchangeable, and the speed of light squared is the constant that relates the two.</p><h2>2. How did Einstein come up with the equation E=mc^2?</h2><p>Albert Einstein developed the equation E=mc^2 as part of his theory of special relativity in 1905. He realized that the speed of light is a fundamental constant in the universe and that it has a direct relationship to mass and energy. Through mathematical calculations and thought experiments, he derived the equation that revolutionized our understanding of the relationship between mass and energy.</p><h2>3. What does the speed of light squared represent in E=mc^2?</h2><p>The speed of light squared, or c^2, represents the amount of energy that is equivalent to a given amount of mass. This means that if you were to convert a certain amount of mass into energy, you would need to multiply it by the speed of light squared to determine the amount of energy produced.</p><h2>4. Is the speed of light squared a constant or a variable in E=mc^2?</h2><p>The speed of light squared, or c^2, is a constant in the equation E=mc^2. This means that it does not change and has the same value in all situations. The speed of light itself, however, is a variable and can change depending on the medium it is traveling through.</p><h2>5. Can E=mc^2 be applied to everyday situations?</h2><p>Yes, E=mc^2 has practical applications in everyday situations. For example, it is used in nuclear energy and nuclear weapons, where mass is converted into energy. It is also used in medical imaging techniques, such as PET scans, which rely on the conversion of mass into energy to create images of the body's tissues and organs.</p>

1. Why is the speed of light squared in E=mc^2?

The speed of light squared, or c^2, is included in the famous equation E=mc^2 because it represents the conversion factor between mass and energy. This means that mass and energy are essentially interchangeable, and the speed of light squared is the constant that relates the two.

2. How did Einstein come up with the equation E=mc^2?

Albert Einstein developed the equation E=mc^2 as part of his theory of special relativity in 1905. He realized that the speed of light is a fundamental constant in the universe and that it has a direct relationship to mass and energy. Through mathematical calculations and thought experiments, he derived the equation that revolutionized our understanding of the relationship between mass and energy.

3. What does the speed of light squared represent in E=mc^2?

The speed of light squared, or c^2, represents the amount of energy that is equivalent to a given amount of mass. This means that if you were to convert a certain amount of mass into energy, you would need to multiply it by the speed of light squared to determine the amount of energy produced.

4. Is the speed of light squared a constant or a variable in E=mc^2?

The speed of light squared, or c^2, is a constant in the equation E=mc^2. This means that it does not change and has the same value in all situations. The speed of light itself, however, is a variable and can change depending on the medium it is traveling through.

5. Can E=mc^2 be applied to everyday situations?

Yes, E=mc^2 has practical applications in everyday situations. For example, it is used in nuclear energy and nuclear weapons, where mass is converted into energy. It is also used in medical imaging techniques, such as PET scans, which rely on the conversion of mass into energy to create images of the body's tissues and organs.

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