PBS Features Einstein's Famous Equation 176
porp writes "On Tuesday, October 11th at 8PM EDT, PBS will feature a docudrama about Einstein's discovery of his famous E=mc^2 equation. The program will include details explaining those who came before him and the development of his miracle year. The pinnacle of which according to the program was his discovery that matter and energy are two sides of the same coin. Yahoo summarizes the program details in length." From the article: "Based on David Bodanis' best-seller 'E=mc2: A Biography of the World's Most Famous Equation,' the program explores the lives of the men and women who helped develop concepts behind each term: E for energy; m for mass; c for the speed of light; and 2 for 'squared,' the multiplication of one number by itself."
Get the formula right. (Score:4, Informative)
Re:Get the formula right. (Score:5, Informative)
E=[(pc)^2 + (mc^2)^2]^(1/2)
Re:Get the formula right. (Score:1)
Re:Get the formula right. (Score:2, Informative)
Its basically taking E^2 - (pc)^2 = mc^2, and the reason this is chosen is because its an invariant quantity, meaning its the same in all inertial reference frames(Real good thing to have to translate between frames).
Re:Get the formula right. (Score:4, Interesting)
The anonymous post above already mentioned that p is for momentum and the equation is framed in a way that accounts for quantum mechanics, not just classical (Newtonian) physics. I found a good explanation here:
http://encyclopedia.laborlawtalk.com/Mass [laborlawtalk.com]Scroll about halfway down to the section header "Relativistic relation among mass, energy and momentum".
By the way, IANAP (I am not a physicist) but I had fun taking physics in college as part of my computer science requirements. And by funny coincidence this post is actually related to my sig. I don't remember where I first saw that (it was in college many moons ago). I always thought it was funny and clever, a good tip of the hat to Mr. Shakespeare, and a good way to describe the universe.Re:Get the formula right. (Score:5, Informative)
The main things to take from E^2 - (pc)^2 = (mc^2)^2:
1. Set the mass m equal to 0. We get E = pc, or p = E/c. Thus momentum is defined for massless particles in special relativity. Newtonian mechanics can't handle this correctly.
2. Set the momentum p equal to 0. We get E = mc^2, popularly known as energy-mass equivalence. There's subtleties to it, though; see Relativistic mass [wikipedia.org].
Re:Get the formula right. (Score:2)
Re:Get the formula right. (Score:2)
Special Relativity was "just" a modification of Newton's equations to make them invariant under the lorenz trasform, instead of the galilean transform. This resolved the conflict between Maxwell's equations and Newton's equations. Out of Einstein's discoveries, this is by far and away the easiest to explain -- essentially he took into account that it to
Re:Get the formula right. (Score:2, Insightful)
E = (mc^2)/sqrt(1-v^2/c^2).
This can be made more intuitive if we note that momentum is defined as
p = mv/sqrt(1-v^2/c^2).
Hence
E^2 - p^2c^2 = m^2c^4 (remember than 1-v^2/c^2 = (c^2-v^2)/c^2 ).
Therefore, if v = 0, E = mc^2. In these equations, m is the rest mass of an object, v is the velocity of the object observed from your reference frame. Both the object and you cannot be acc
It's a semantics, the formula WAS right (Score:5, Interesting)
Re:Get the formula right. (Score:1)
Re:Get the formula right. (Score:2, Insightful)
Re:Get the formula right. (Score:1)
Meaning of "summarises program details in length" (Score:4, Funny)
True origin of the famous equation (Far Side) (Score:4, Funny)
Your desk is all squared away. Yep, all squaaaaaaaaaaaared away. (I couldn't find an image to link to--sorry!
Re:True origin of the famous equation (Far Side) (Score:2, Funny)
Re:True origin of the famous equation (Far Side) (Score:2)
The great Houdini escapes a black hole!
(Ok, it wasn't about Einstein, but $10 says he would have chuckled.)
Re:True origin of the famous equation (Far Side) (Score:2)
However, these hypothetical objects were not the topic of much interest until the late 1960s. Most physicists believed that they were a peculiar feature of the highly symmetric solution found by Schwarzschild, and that objects collapsing in nature would not form black holes.
Albert Einstein died in 1955.
Oh.. you meant the other one.. Baby Einstein, right?
I'll take that 10$ in Sqrt(-1) bills.
Re:True origin of the famous equation (Far Side) (Score:2)
Oh.. you meant the other one.. Baby Einstein, right?"
Um, no. You see, I used a couple of words in my post that you might have found somewhat interesting. They were would and have.
WTF @ summary (Score:5, Insightful)
Re:WTF @ summary (Score:2, Insightful)
Re:WTF @ summary (Score:3, Insightful)
As one complains when Bush does nothing, or when he does something stupid.
Read the book (Score:1)
Re:WTF @ summary (Score:2)
No, really.
Re:WTF @ summary (Score:2)
The book is interesting because it offers some 'petite histoire' on the evolution of the formula. Unfortunately you have a point that it is not completely for nerds as it contains fuzzy explanations and crappy analogies here and there. (discla
Re:WTF @ summary (Score:2)
Re:WTF @ summary (Score:2)
Yes. Everyone knows that E=mc^2 means that you're turning on the second least significant bit in the variable mc and assigning that to E.
Buying my own copy (Score:2)
Re:Buying my own copy (Score:1)
Re:Buying my own copy (Score:1)
Re:Buying my own copy (Score:2)
A little help... (Score:1)
Re:A little help... (Score:1)
Energy * time = mass * speed of light * gravity
Say, at the big crunch, all matter in the universe is heading toward a center
Re:A little help... (Score:2)
Piling on the info, the form of the equation in grandparent is not wrong -- it's a special case. For all the reasons stated by parent it becomes wrong because this form of the equation is a result derived of "Special Relativity". "Special" means your reference frame is not accelerating , etc. "General Relativity" gives you the complete version of this equation in all frames, but my copy of Jackson is in the attic at my folks' house so I can't dig it out for you now -- it's almost time to leave for church.
Re:A little help... (Score:2)
General Relativity requires LOTS of higher level math (which most /.'ers won't have). Feynman's lectures have a decent non-math description of it, and I think Penrose's book has an explaination.
Re:A little help... (Score:2)
I might be mistaken, but I thing it's the same book -- there's a short optional/supplemental section on it in one of the later chapters, IIRC. At the end of the class, our EM prof gave us a choice between GR (which is of almost no practical use) and wave guides (which you can use to make $$) and we picked GR.
The funny part is that the math is almost all matrix mechanics, like optics, but to save space and make the equations look less encumbered you write everything out in Einstein notation. Insteaed of w
Re:A little help... (Score:2)
Re:A little help... (Score:2)
Not sure - it's been a while for me too, but I believe the matrix representation of the math is an expression of tensors. I don't remember manifolds being directly involved, but they probably were and he just didn't tell us that. For some reason I think manifolds came afterward, historically, but I might be hallucinating. Maybe they were a latter-day addition to modernize the theory and make it more compact?
Want to see something hilarious? Two old-school
Animaniacs (Score:5, Funny)
Re:Animaniacs (Score:1)
Already out on digitaldistractions (Score:2, Informative)
It's a pretty interesting show.
Get it right! (Score:1, Funny)
Neat but one burning question (Score:2, Interesting)
--
If life was simple, there simply wouldn't be any life
--
Re:Neat but one burning question (Score:1)
Re:Neat but one burning question (Score:2)
"varying" speeds of light (Score:4, Interesting)
While people may have set up interesting media through which light travels at some odd speed, no one has ever observed light traveling through a vacuum at other than c. Indeed, it's a bedrock principle of relativity that it cannot.
Interestingly, the eerie blue glow [umr.edu] you see coming from nuclear reactor cores that live at the bottom of pools of water (called Cerenkov radiation) is emitted by particles coming from the core that are traveling faster than the speed of light in water (although of course slower than c). The blue light is a sort of "optic boom" similar in its origin to the "sonic boom" you hear from aircraft exceeding the speed of sound.
Re:"varying" speeds of light (Score:1)
Re:"varying" speeds of light (Score:2)
Cerenkov radiation moves faster than light does in in water (about 2/3 c, IIRC), not in vacuum. There wouldn't be any Cerenkov radiation at all in vacuo, since it's caused by particles hitting water. But more importantly, the "swimming pool reactor" would melt down in vacuum.
Re: more clarification... (Score:2)
I think you'll find that the theories show nothing can traverse the s.o.l boundary, that still allows for superluminal particles but makes them hard/impossible to detect.
http://scienceworld.wolfram.com/physics/Superlumin al.html [wolfram.com]
Tachyons aren't just a plot tool for StarTrek script writers!
Re:Neat but one burning question (Score:3, Informative)
Re:Neat but one burning question (Score:2)
Given scientests have managed to make light go slower
That's not entirely accurate. The speed of actual photons always travels at C. The speed of propogation of a light signal doesn't always travel at C. The difference is that when light travels through a medium it's absorbed, and then re-emitted by atoms. This takes some amount of time that takes more time than it would normally take to cross the distance of an atom. It's kind of like having a bunch of people in a line far apart playing telephone. You
Rolling in the grave (Score:2, Insightful)
I've seen this already I think (Score:4, Interesting)
Re:I've seen this already I think (Score:1)
I really enjoyed it (Score:3, Informative)
Oh, and as a bonus, it's narrated by Christopher Eccleston. Half expected to hear a metal scream ring out at any moment. "Exterminate!"
The real question is (Score:2)
Seen it already (Score:2, Informative)
Rest Mass (Score:4, Informative)
People should realize that the M in e=mc^2 is not the widely known idea of mass. Most people think that a bowling ball that weighs 10 pounds has a set mass no matter what. But in Einstein's equation mass is more like inertia. A moving bowling ball has more mass than one at rest. So you can not simply take a 10 kilogram object and multiply it by the speed of light squared to get its energy. This means you must first complete the equation for m first, which I do not know off hand.
So the idea of mass that most people know is called rest mass. It took me a while to realize that they meant an object could increase mass but gain no atoms or extra "material". Since most objects we can see and touch don't even go 1% the speed of light, we never notice this increase. For almost all practical cases(even a plan going mach 3) we can consider its mass to be rest mass and still be accurate to within many many decimal places.
Re:Rest Mass (Score:1)
Re:Rest Mass (Score:1)
c^2 unnecessary? (Score:2)
Why have the c^2 part at all? Is the energy contained in an object really variable based upon the speed of light in a particular
Re:c^2 unnecessary? (Score:2)
Um, c isn't the speed of a particular beam of light in any sense (which, as you say, changes depending on the medium). c is the speed of light in a vacuum, and is constant.
So the equation is really just E = M.
Yes, it is, when you use Planck units [wikipedia.org], which simplify this and other equations by setting certain constants to 1. You are just converting between units, because the
Re:Rest Mass (Score:2)
The contribution from motion, that you are referring to, is contained in the second term of the [full] relation:
E^2 = (mc^2)^2 + (pc)^2, where p is simply the momentum of the object.
Mike.
Re:Rest Mass (Score:2)
You use the conversion factor sqrt(1-v^2/c^2) (let's call that k), where v=velocity and c=speed of light. The relativistic mass of an object is 1/k of its rest mass. The relativistic length of an object in the direction that it's moving shrinks to k times is length. Time also dilates by t=rest t/k, which is how Mazer Rackham got to live for hundreds years by traveling at high speeds and thus having a low k.
The easy way
PBS Scientific Documentaries (Score:2)
Einstein's Wife (Score:3, Interesting)
Anyway, it's a good complementary read:
http://www.pbs.org/opb/einsteinswife/science/inde
Re:Einstein's Wife (Score:3, Interesting)
Not that I am an Einstein hater, but he really was a rotten husband and father.
But the real question... (Score:2)
Multiplication by itself?!?!? (Score:2)
Thank you Einstein for making such a marvelous discovery!!!
I'm still iffy about the name.. "square"? Is this geometry or astrologics? Get it straight, please.
WATCH IT! (Score:2)
Its brilliant.
Measurement Units? (Score:2)
Or does C have to be in units relative to the resting state of the observer? And in that case does the energy in a given mass by another observer change . And still what is to say that an observer doesn't go around talking in stellar units rather than anything smaller than that (again c^2 1)?
Re:Measurement Units? (Score:3, Informative)
But a light-second is huge, and a light-second squared is even huger. In fact, of course, 1 ls ~= 3 * 10^8 m, and thus 1 ls^2 ~= 9 * 10^16 m^2. (
Re:Measurement Units? (Score:2)
c in centimeters/second, m in grams, gives e in Ergs
This is not a coincidence or anything. A Joule is by definition the work done by a force of 1 Newton pushing something 1 meter. Meanwhile a Newton is the force which, applied to 1 kilogram body will accelerate it at 1 meter/second/second, so a Joule is a kilogram meter^2/second^2. A similar story holds for centimeters, grams and ergs.
So, you can get a truly unit free formulation: the energy equivalent of
Squares With Geometry (Score:2)
Re:Squares With Geometry (Score:2)
Curved Spaceballs (Score:2)
Ah. the theory of relativity (Score:2)
2 for 'squared' (Score:2)
Thanks Yahoo, and Slashdot (or is it Sesame Street?)
Heaviside's Equation (Score:3, Interesting)
As I've pointed out before on
Einstein's contribution was to show that what these others derived from a dynamical theory could be understood in kinematic terms. Dynamics is the study of the causes of motion, and kinematics is the description of motion. In the pre-Einstein theory the resistance of the electron to motion--and the contraction of moving electrons in the direction of motion--was understood as due to electro-magnetic forces acting on it due to the aether. What Einstein showed was that the same phenomena could be understood in purely kinematic terms, as a consequence of the way motion must be described if the laws of physics are to be the same for all observers.
To get a sense of how profound this is, imagine that at one time the inverse-square law for light had been understood in terms of an absorbing medium. That is, the fact that lights appeared dimmer as the square of the distance to the observer was explained by empty space being filled with a substance that absorbed light. There would be many difficulties with such a theory, but I'm sure with sufficient mathematical prowess one could make it work. Then someone like Einstein comes along and points out that one can explain the phenomenon in purely geometric terms, as a consequence of the way the light is spreading out over the surface of a larger sphere as it gets further from the source. What previously required a complex, difficult mathematical description now becomes so trivial that even a philosopher can understand it.
That was Einstein's contribution, but it shouldn't completely eclipse the work of those who came before.
here's the torrent of the show, already been on tv (Score:2)
http://www2.digitaldistractions.org:8080/torrents/ E=mc2%20-%20Einstein%20And%20The%20Worlds%20Most%2 0Famous%20Equation.torrent [digitaldistractions.org]
if the link doesn't work go to http://www2.digitaldistractions.org:8080/ [digitaldistractions.org] and search for e=
SPOILER: Here's the drama... (Score:2)
E = mb^2
E = mc^2 !!!!!
how much did wife Mileva help him? (Score:2)
Re:Well... (Score:1)
Re:Well... (Score:2)
E^(Pi * i)+1=0
(plus, not minus)
I always though E^(iPi)=-1 fit more tightly, or even E^(iPi)=i^2.
Re:Well... (Score:2)
Re:last part of write-up was great (Score:1, Insightful)
Re:last part of write-up was great (Score:5, Funny)
As to why would someone be interested in E=mc^2 without knowing the concept of "squared", you obviously don't understand business. We can't limit the target audience of our movie to only the few people who know about "squared".
Re:last part of write-up was great (Score:2, Insightful)
It shows the willingness of people to remain ignorant of so many things, and concern themselves utterly with the trivial.
Re:last part of write-up was great (Score:1)
Well thank goodness slashdot is here to educate us all, otherwise I would be off doing something completely trivial! Where's that link to the "Intelligent Door Handle" thread... Oh wait....
Re:last part of write-up was great (Score:3, Funny)
Re:Einstein was wrong (Score:2)
Here's the guy (horrendous quality):
http://www.autodynamics.org/einstein_wrong.html
-1 Pseudoscience (Score:2, Interesting)
They claim that frames of reference don't actually exist. I don't see why not, but that leaves you with a theory that is completely unable to meaningfully describe any phenomenon that is not standing still. Try to calculate the orbits of a moving Bohr atom, using A
Re:-1 Pseudoscience (Score:2)
Re:Is this new? (Score:1)
I checked this out a few weeks ago. It's really an interesting show depicting some of the greats that preceeded Einstein as well.
Re:Is this new? (Score:3, Informative)
I checked this out a few weeks ago. It's really an interesting show depicting some of the greats that preceeded Einstein as well.
Re:Is this new? (Score:2)
Thanks for the link.
You... (Score:1, Offtopic)
'Simple' is right (Score:2)
That page is full of nonsense, and the derivation is nonsense as well. Where does 'p = E/c' come from?
Looks like that whole page is one big troll... someone has too much time on their hands.
Re:'Simple' is right (Score:2)
Actually, looking at that page again, they're selling something... their book on how everything in modern science is wrong. Heh. Not a good place to go for scientific information, then :p
Re:Simple derivation of this equation (Score:2)
Glad to see some other slashdotters have been Saved here. Praise spaghetti!