Please explain to me why the speed of light is squared

[Nusc]

E = mc^2

Please explain to me why the speed of light is squared.

 

[dextercioby]

Write it

$$E=m^{a}c^{b}$$

and from the units get the values of "a" & "b".

Daniel.

 

[Nusc]

I don't understand what you mean. What logic was involved that determined whether the energy-mass relationship was proportional to the speed of light squared?

 

[dextercioby]

It follows from the unit analysis that E~m_{0}c^{2} and equal to it from the postulates.

Daniel.

 

[Dr.Brain]

dextercioby is trying to prove you the formula through the dimension analysis

For E, the dimensions are $ML^2 T^-2$

As E=mc^2 , keeping aside M , we are left with $L^2 T^-2$ which is a dimension for $c^2$ ... as dimension for a velocity is $LT^-1$

 

[Nusc]

I'm sorry. I wasn't aware if there was any specific mathematics involved.

Can you specify which courses are?

 

[pervect]

The topic is called "dimensional analysis" as others have written. It's usually taught as a part of standard physics courses (High school physics, I think, I'm not sure anymore).

Google for the term "dimensional analysis" or try

http://www.physics.uoguelph.ca/tutorials/dimanaly/

 

[Nusc]

Oh man. What was I talking about?!

haha damn

kg * (m/s)^2 = J

 

[z-component]

Yes, it is taught in high school.

 

[rbj]

but dimensional analysis isn't enough to show why $E = m c^2$. perhaps it's

$$E = \frac{1}{2} m c^2$$

or

$$E = m c v$$

or

$$E = \frac{m c^3}{v}$$

where $$v$$ is the velocity of my daughter's bicycle at full clip. those are both dimensionally correct. or maybe it's

$$E = \frac{(m c)^2}{m_e}$$

where $$m_e$$ is the mass of the electron.

all of these are dimensionally correct, but they ain't correct.

r b-j

 

[James Jackson]

Firstly, in your counter-argument for the dimensional analysis, you're ignoring the fact that the 'full' equation really reads

$$E^2=m^2c^4+p^2c^2$$

So in the case where the particle is at rest, this simplifies to $E=mc^2$. Anywho, ignoring all that, the equation is pretty simply derived by applying the relativistic Lorentz transforms to energy and momentum. The transforms themselves are derived from the postulates of special relativity (Physical laws hold in all inertial reference frames and the speed of light is constant in all intertial reference frames).

 

[rbj]

Firstly, in your counter-argument for the dimensional analysis, you're ignoring the fact that the 'full' equation really reads

$$E^2=m^2c^4+p^2c^2$$

So in the case where the particle is at rest, this simplifies to $E=mc^2$. Anywho, ignoring all that, the equation is pretty simply derived by applying the relativistic Lorentz transforms to energy and momentum. The transforms themselves are derived from the postulates of special relativity (Physical laws hold in all inertial reference frames and the speed of light is constant in all intertial reference frames).

something happened to the textbook notation since i was in school. i was taught (ca. 1975) that the famous equation

$$E =m c^2$$

resulted from an interpretation of the derivation of the relativistic kinetic energy of a particle taking into consideration of the change in mass due to relativistic considerations.

Kinetic energy: $$T = m c^2 - m_0 c^2$$

where $$m = \frac{m_0}{\sqrt{1-\frac{v^2}{c^2}}}$$

and $$m_0$$ is the rest mass. then we rearraged and interpreted that equation as

$$m c^2 = m_0 c^2 + T$$

or $$E = E_0 + T$$

or "total energy equals rest energy plus kinetic energy."

if $$m$$ is the relativistic mass,

$$E = m c^2$$ is the full equation.

if i plug everything in

$$E = m c^2 = \frac{m_0 c^2}{\sqrt{1-\frac{v^2}{c^2}}}$$

$$E^2 = \frac{m_0^2 c^4}{1-\frac{v^2}{c^2}}$$

i s'pose it comes out to what you're saying is the full equation when $$|v| << c$$. i don't assume $$m$$ is the rest mass.

(new edit)

okay, i just worked it out and there is no need for $$|v| << c$$.

$$E^2 = \frac{m_0^2 c^4}{1-\frac{v^2}{c^2}}$$

means

$$E^2 \left( 1-\frac{v^2}{c^2} \right) = m_0^2 c^4$$

$$E^2 -\frac{E^2 v^2}{c^2} = m_0^2 c^4$$

$$E^2 -\frac{(m c^2)^2 v^2}{c^2} = m_0^2 c^4$$

$$E^2 - (m v c)^2 = m_0^2 c^4$$

$$E^2 - p^2 c^2 = m_0^2 c^4$$

$$E^2 = m_0^2 c^4 + p^2 c^2$$

still, $$E = m c^2$$ is the "full" equation if $$m$$ is relativistic mass.

r b-j

 

[James Jackson]

In that 'derivation' you're assuming that $E=mc^2$ to begin with. Einstein derived it by looking at momentum carrying photons being emitted and adsorbed.

Anyway, I can't see how your final equation can possibly become $E^2=m^2c^4+p^2c^2$ (note this is Lorentz invarient - it holds in any frame).

 

[Nomy-the wanderer]

Well when u derive E=mc² u begin by integrating the kinetic energy, the actual start point is KE=1/2 mv²...

 

[Nusc]

In that 'derivation' you're assuming that $E=mc^2$ to begin with. Einstein derived it by looking at momentum carrying photons being emitted and adsorbed.

That will suffice

 

[juvenal]

In that 'derivation' you're assuming that $E=mc^2$ to begin with. Einstein derived it by looking at momentum carrying photons being emitted and adsorbed.

Anyway, I can't see how your final equation can possibly become $E^2=m^2c^4+p^2c^2$ (note this is Lorentz invarient - it holds in any frame).

He actually starts with the relativistic mass = m.

$$E = m c^2<br /> = \gamma m_0 c^2$$

 

[rbj]

In that 'derivation' you're assuming that $E=mc^2$ to begin with.

no, James. the assumption that i started with was the relativistic expression of kinetic energy:

$$T = m c^2 - m_0 c^2$$

where $m$ is the relativistic mass. do you disagree with that? will i have to derive that? (it's a b!tchier job than i want to do.) then we interpret that to be

$$T = E - E_0$$

or

$$E = E_0 + T$$ .

are you okay with that? BTW, it ain't hard to show that

$$T = m c^2 - m_0 c^2$$

becomes

$$T = \frac{1}{2} m_0 v^2$$

in the limit as $|v| << c$.

Einstein derived it by looking at momentum carrying photons being emitted and adsorbed.

perhaps ... i dunno. i am only reverberating what is in my "modern" physics textbook and it's a treatment that i understand. i don't know how they teach it now.

Anyway, I can't see how your final equation can possibly become $E^2=m^2c^4+p^2c^2$ (note this is Lorentz invarient - it holds in any frame).

remember, my $m$ ain't the same as your $m$. your $m$ is my $m_0$. all's i was doing was showing that

$$E^2 = m_0^2 c^4 + p^2 c^2$$

is consistent with

$$E = m c^2$$

where $$m = \frac{m_0}{\sqrt{1 - \frac{v^2}{c^2}}}$$

and $$p = m v$$.

r b-j

 

[James Jackson]

"the assumption that i started with was the relativistic expression of kinetic energy"

You said it yourself. This isn't a derivation of $E=mc^2$ as you started with that!

 

[rbj]

"the assumption that i started with was the relativistic expression of kinetic energy"

You said it yourself.

but it's not what you said. you said that i started with the assumption $E = m c^2$ and i said that i started with $T = m c^2 - m_0 c^2$.

you said that there was no way you could see how i could get $E^2 = m^2 c^4 + p^2 c^2$ from $E = m c^2$ and i said that did get $E^2 = m_0^2 c^4 + p^2 c^2$ from $E = m c^2$ and i showed how.

This isn't a derivation of $E=mc^2$ as you started with that!

no, i started with $T = m c^2 - m_0 c^2$ and i never attempted to prove it. i did not start with $E = m c^2$.

i don't know if you're intending to prop a straw man up or not, but where can you quote me where i said i was deriving $E = m c^2$?

my only intention in adding to this thread was to point out that dimensional analysis was insufficient to point out why it's $E = m c^2$. there are a zillion incorrect physical equations that are dimensionally correct. if you're going to assume that it's $E = m^a c^b$, then dimensional analysis is sufficient to show that $a = 1$ and $b = 2$, and, perhaps that is sufficient to answer the OP's question. but it doesn't answer why it's $E = m c^2$.

dimensional analysis can really only be used to prove that some physical equation is wrong. it is not sufficient to prove that any physical equation is right. if a derived equation comes out to be dimensionally inconsistent across "=" or "+" or "-" signs, then you know something is wrong and you may as well not proceed further with it until you fix the problem.

if you want a derivation for $E = m c^2$ or for $T = m c^2 - m_0 c^2$, i might suggest getting a textbook. I'm too lazy to.

perhaps, James, you would be kind enough to post a derivation.

r b-j