Can you Explain what the equation E=mc2 means?

Answer 1

This is Einsteins theory of relativity where he realized Matter can be turned into energy, and energy into matter.
In this equation;
E = energy (measured in joules, J)
m = mass (measured in kilograms, Kg)
c = the speed of light (measured in metres per second)

It means that mass and energy are basically the same thing, in a around about way, mass can be converted to energy and energy can become mass. they are relative to each other.
uou can find more details at http://www.aip.org/history/einstein/voic...

Answer 2

Energy equals mass (multiplied by) circumfurence (to the 2nd power)

so anotherwords
if you spin a small object around in a circle, you are creating energy
but if you spin a large object around the same circle
you are creating more energy than using the small one

It gets a lot more complicated but tahts just a dumbed down version for non-geniuses

Answer 3

E = energy (measured in joules, J)
m = mass (measured in kilograms, Kg)
c = the speed of light (measured in metres per second)

It means that mass and energy are basically the same thing, in a around about way, mass can be converted to energy and energy can become mass. they are relative to each other.
( do a google on "Special theory of relativity"

have fun

Answer 4

Listen to Einstein explain his equation for the theory of relativity.

Answer 5

I tis the total amount of energy that a mass would give off if it were entirely converted to energy. Energy = Mass X speed of light squared.

Answer 6

One of Einstein's great insights was to realize that matter and energy are really different forms of the same thing. Matter can be turned into energy, and energy into matter.
For example, consider a simple hydrogen atom, basically composed of a single proton. This subatomic particle has a mass of

0.000 000 000 000 000 000 000 000 001 672 kg
This is a tiny mass indeed. But in everyday quantities of matter there are a lot of atoms! For instance, in one kilogram of pure water, the mass of hydrogen atoms amounts to just slightly more than 111 grams, or 0.111 kg.
Einstein's formula tells us the amount of energy this mass would be equivalent to, if it were all suddenly turned into energy. It says that to find the energy, you multiply the mass by the square of the speed of light, this number being 300,000,000 meters per second (a very large number):
E=MC^2=
= 0.111 x 300,000,000 x 300,000,000
= 10,000,000,000,000,000 Joules

This is an incredible amount of energy! A Joule is not a large unit of energy ... one Joule is about the energy released when you drop a textbook to the floor. But the amount of energy in 30 grams of hydrogen atoms is equivalent to burning hundreds of thousands of gallons of gasoline!


If you consider all the energy in the full kilogram of water, which also contains oxygen atoms, the total energy equivalent is close to 10 million gallons of gasoline!
Can all this energy really be released? Has it ever been?

The only way for ALL this energy to be released is for the kilogram of water to be totally annhilated. This process involves the complete destruction of matter, and occurs only when that matter meets an equal amount of antimatter ... a substance composed of 'negative mass'. Antimatter does exist; it is observable as single subatomic particles in radioactive decay, and has been created in the laboratory. But it is rather short-lived (!), since it annihilates itself and an equal quantity of ordinary matter as soon as it encounters anything. For this reason, it has not yet been made in measurable quantities, so our kilogram of water can't be turned into energy by mixing it with 'antiwater'. At least, not yet.

Another phenomenon peculiar to small elementary particles like protons is that they combine. A single proton forms the nucleus of a hydrogen atom. Two protons are found in the nucleus of a helium atom. This is how the elements are formed ... all the way up to the heaviest naturally occuring substance, uranium, which has 92 protons in its nucleus.
It is possible to make two free protons (Hydrogen nuclei) come together to make the beginnings of a helium nucleus. This requires that the protons be hurled at each other at a very high speed. This process occurs in the sun, but can also be replicated on earth with lasers, magnets, or in the center of an atomic bomb. The process is called nuclear fusion.
What makes it interesting is that when the two protons are forced to combine, they don't need as much of their energy (or mass). Two protons stuck together have less mass than two single separate protons!
When the protons are forced together, this extra mass is released ... as energy! Typically this amounts to about 7% of the total mass, converted to an amount of energy predictable using the formula .E=MC^2

Elements heavier than iron are unstable. Some of them are very unstable! This means that their nuclei, composed of many positively charged protons, which want to repel from each other, are liable to fall apart at any moment! We call atoms like this radioactive.
Uranium, for example, is radioactive. Every second, many of the atoms in a chunk of uranium are falling apart. When this happens, the pieces, which are now new elements (with fewer protons) are LESS massive in total than the original uranium atoms. The extra mass disappears as energy ... again according to the formula ! This process is called nuclear fission.

Both these nuclear reactions release a small portion of the mass involved as energy. Large amounts of energy! You are probably more familiar with their uses. Nuclear fusion is what powers a modern nuclear warhead. Nuclear fission (less powerful) is what happens in an atomic bomb (like the ones used against Japan in WWII), or in a nuclear power plant.

Albert Einstein was able to see where an understanding of this formula would lead. Although peaceful by nature and politics, he helped write a letter to the President of the United States, urging him to fund research into the development of an atomic bomb ... before the Nazis or Japan developed their own first. The result was the Manhatten Project, which did in fact produce the first tangible evidence of ... the atomic bomb!

Answer 7

i've read somewhere that it's related to the TIME! and it was by Albert Einstein! with this formula he entered in the world of atom

Answer 8

E=mc2 is one of the most famous equations in physics, even to non-physicists. It states a relationship between energy (E), in whatever form, and mass (m). In this formula, c², the square of the speed of light in a vacuum, is the conversion factor required to formally convert from units of mass to units of energy, i.e. the energy per unit mass. In unit-specific terms, E (joules) = m (kilograms) multiplied by (299792458 m/s)2.

The equation was first published in a slightly different formulation by Albert Einstein in 1905 in one of his famous articles. He derived it as a consequence of the special theory of relativity which he had proposed the same year
This formula proposes that when a body has a mass (measured at rest), it has a certain (very large) amount of energy associated with this mass. This is opposed to the Newtonian mechanics, in which a massive body at rest has no kinetic energy, and may or may not have other (relatively small) amounts of internal stored energy (such as chemical energy or thermal energy), in addition to any potential energy it may have from its position in a field of force. That is why a body's rest mass, in Einstein's theory, is often called the rest energy of the body. The E of the formula can be seen as the total energy of the body, which is proportional to the mass of the body.

Conversely, a single photon travelling in empty space cannot be considered to have an effective mass, m, according to the above equation. The reason is that such a photon cannot be measured in any way to be at "rest" and the formula above applies only to single particles when they are at rest. Photons are generally considered to be "massless," (i.e., they have no rest mass or invariant mass) even though they have varying amounts of energy.

This formula also gives the quantitative relation of the quantity of mass lost from a resting body or an initially resting system, when energy is removed from it, such as in a chemical or a nuclear reaction where heat and light are removed. Then this E could be seen as the energy released or removed, corresponding with a certain amount of mass m which is lost, and which corresponds with the removed heat or light. In those cases, the energy released and removed is equal in quantity to the mass lost, times the speed of light squared. Similarly, when energy of any kind is added to a resting body, the increase in the resting mass of the body will be the energy added, divided by the speed of light squared.

History and consequences
Albert Einstein derived the formula based on his 1905 inquiry into the behavior of objects moving at nearly the speed of light. The famous conclusion he drew from this inquiry is that the mass of a body is actually a measure of its energy content. Conversely, the equation suggests (see below) that all of the energies present in closed systems affect the system's resting mass.


According to the equation, the maximum amount of energy "obtainable" from an object to do active work, is the mass of the object multiplied by the square of the speed of light.

It was actually Max Planck who first pointed out that Einstein's equation implied that bound systems would have a mass less than the sum of their constituents, once the binding energy had been allowed to escape. However, Planck was thinking in terms of chemical reactions, which have binding energies too small for the measurement to be practical. Early experimentors also realized that the very high binding energies of the atomic nuclei should allow calculation of their binding energies from mass differences, however it was not till the discovery of the neutron and its mass in 1932 that this calculation could actually be performed. Very shortly thereafter, the first transmutation reactions (such as 7Li + p → 2 4He ) were able to verify the correctness of Einstein's equation to an accuracy of 1%.

This equation was used in the development of the atomic bomb. By measuring the mass of different atomic nuclei and subtracting from that number the total mass of the protons and neutrons as they would weigh separately, one could obtain an estimate of the binding energy available within an atomic nucleus. This could and was used in estimating the energy released in the nuclear reaction, by comparing the binding energy of the nuclei that enter and exit the reaction.

It is a little known piece of trivia that Einstein originally wrote the equation in the form Δm = L/c² (with an "L", instead of an "E", representing energy, the E being utilised elsewhere in the demonstration to represent energy too).

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Practical examples
A kilogram of mass could (theoretically) convert completely into

89,875,517,873,681,764 joules (exactly) or
24,965,421,632 kilowatt-hours or
21.48076431 megatons of TNT
approximately 0.0851900643 Quads (quadrillion British thermal units)
It is important to note that practical conversions of "mass" to energy are seldom 100 percent efficient. One theoretically perfect conversion would result from a collision of matter and antimatter (e.g. in positronium experiments); for most cases, byproducts are produced instead of energy, and therefore very little mass is actually converted. For example, in nuclear fission roughly 0.1% of the mass of fissioned atoms is converted to energy. In turn, the mass of fissioned atoms is only part of the mass of the fissionable material: e.g. in a nuclear fission weapon, the efficiency is 40% at most. In nuclear fusion roughly 0.3% of the mass of fused atoms is converted to energy.

In the equation, mass is energy, but for the sake of brevity, the word "converted" is used; in practice, one kind of energy is converted to another, but it continues to contribute mass to systems so long as it is trapped in them (active energy is associated with mass also, as seen by single observers). Thus, the total mass of any system is conserved and remains unchanged (for any single observer) unless energy (such as heat, light, or other radiation) is allowed to escape the system. In any cases, the use of the phrase "converted" is intended to signify energy which has gone from passive potential energy, into heat or kinetic energy which can be used to do work (as in a nuclear reactor or even in a heat-producing chemical reaction).

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Background
E = mc² where m stands for rest mass (invariant mass), applies to all objects or systems with mass but no net momentum. Thus, it applies most simply to particles which are not in motion. However, in a more general case, it also applies to particle systems (such as ordinary objects) in which particles are moving but in different directions so as to cancel momentums. In the later case, both the mass and energy of the object include contributions from heat and particle motion, but the equation continues to hold.

The equation is a special case of a more general equation in which both energy and net momentum are taken into account. This equation applies to a particle that is not moving as seen from a reference point, but this same particle can be moving from the standpoint of other frames of reference. In such cases, the equation must become more complicated as the energy changes, since momentum terms must be added so that the mass remains constant from any reference frame.

Alternative formulations of relativity, see below, allow the mass to vary with energy and ignore momentum, but this involves use of a second definition of mass, called relativistic mass because it causes mass to differ in different reference frames.

A key point to understand is that there may be two different meanings used here for the word "mass". In one sense, mass refers to the usual mass that someone would measure if sitting still next to the mass, for example. This is the concept of rest mass, which is often denoted m0. It is also called invariant mass. In relativity, this type of mass does not change with the observer, but it is computed using both energy and momentum, and (unless momentum happens to be zero) the equation E = mc2 is not in general correct for it, if the total energy is wanted. (In other words, if this equation is used with constant invariant mass or rest mass of the object, the E given by the equation will always be the constant rest energy of the object, and will not change with the object's motion).

In developing special relativity, Einstein found that the total energy of a moving body is


with v being the relative velocity. This can be shown to be equivalent to


with p being the relativistic momentum (ie. p = γp0 = mrel * v).

When v = 0, then p = 0, and both formulas above reduce to E = m0c2, with E now representing the rest energy, E0. This can be compared with the kinetic energy in newtonian mechanics:

,
where E0 = 0 (in Newtonian mechanics only kinetic energy is treated, and thus "rest energy" is zero).

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Relativistic mass
After Einstein first made his proposal, some suggested that the mathematics might seem simpler if we define a different type of mass. The relativistic mass is defined by


Using this form of the mass, we can again simply write E = mrelc2, even for moving objects. Now, unless the velocities involved are comparable to the speed of light, this relativistic mass is almost exactly the same as the rest mass. That is, we set v = 0 above, and get mrel = m0.

Now, understanding the difference between rest mass and relativistic mass, we see that the equation E = mc2 in the title must be rewritten: either E = m0c2 for v = 0, or E = mrelc2 when .

Einstein's original papers (see, e.g. [1]) treated m as what would now be called the rest mass or invariant mass and he did not like the idea of "relativistic mass" (see usenet physics FAQ [2]). When a modern physicist refers to "mass," he or she is almost certainly speaking about rest mass, also. This can be a confusing point, though, because students are sometimes still taught the concept of "relativistic mass" in order to be able to keep Einstein's simple equation correct, even for moving bodies.

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Low-speed approximation
We can rewrite the expression above as a Taylor series:


For speeds much smaller than the speed of light, higher-order terms in this expression (the ones farther to the right) get smaller and smaller. The reason for this is that the velocity v is much smaller than c, so v / c is quite small. If the velocity is small enough, we can throw away all but the first two terms, and get


This expresses energy as the sum of Einstein's term for a resting object and the usual kinetic energy which Newton knew about. Thus, we see that Newton's form of the energy equation just ignores the parts that he never knew about: the m0c2 part, and the high-speed parts. This worked because Newton never saw an object lose enough energy to measurably change its rest mass--as in a nuclear process--and only saw objects move at speeds which were quite small compared to the speed of light. Einstein needed to add the extra terms to make sure his formula was right, even at high speeds. In doing so, he discovered that rest mass could be "converted" to energy (or more correctly, converted to active energy which retained mass, but which could be drained away as heat or radiation, so that it subtracted from rest mass when gone).

Interestingly, we could include the m0c2 part in Newtonian mechanics because it is constant, and only changes in energy have any influence on what objects actually do. This would be a waste of time, though, precisely because this extra term would not have any noticeable effect, except at the very high energies characteristic of nuclear reactions or particle accelerators. The "higher-order" terms that we left out show that special relativity is a high-order correction to Newtonian mechanics. The Newtonian version is actually wrong, but is close enough to use at "low" speeds, meaning low compared with the speed of light. For example, all of the celestial mechanics involved in putting astronauts on the moon could have been done using only Newton's equations.

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Einstein and his 1905 paper
Albert Einstein did not formulate exactly this equation in his 1905 paper "Ist die Trägheit eines Körpers von seinem Energieinhalt abhängig?" ("Does the Inertia of a Body Depend Upon Its Energy Content?", published in Annalen der Physik on September 27), one of the articles now known as his Annus Mirabilis Papers.

That paper says: If a body gives off the energy L in the form of radiation, its mass diminishes by L/c², "radiation" being electromagnetic radiation in Einstein's example (the paper specifies "light"), and the mass being the ordinary concept of mass used in those times, the same one that today we call rest energy or invariant mass, depending on the context. Einstein's very first formulation of this equation asserts that the invariant mass of a body does not change until the system is opened and light or heat is removed.

In Einstein's first formulation, it is the difference in the mass '' before the ejection of energy and after it, that is equal to L/c², not the entire mass '' of the object. At that moment in 1905, even this was only theoretical and not proven experimentally. Not until the discovery of the first type of antimatter (the positron in 1932) was it found that entire pairs of resting particles could be converted to radiation moving away at the speed of light.

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Contributions of others
Einstein was not the only one to have related energy with mass, but he was the first to have presented that as a part of a bigger theory, and even more, to have deduced the formula from the premises of this theory. According to Umberto Bartocci (University of Perugia historian of mathematics), the equation was first published two years earlier by Olinto De Pretto, an industrialist from Vicenza, Italy, though this is not generally regarded as true or important by mainstream historians. Even if De Pretto introduced the formula, it was Einstein who connected it with the theory of relativity.

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Television biography
E=mc² was used as the title of a 2005 television biography about Einstein concentrating on the year 1905.

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Derivation
Newton's second law as it appears in nonrelativistic classical mechanics reads


where mv is the nonrelativistic momentum of a body, F is the force acting upon it, and t is the coordinate of absolute time. In this form, the law is incompatible with the principles of relativity; the law does not change covariantly under Lorentz transformations. This situation is naturally remedied by modifying the law to read


where now p=mγc is the relativistic momentum of the body, F is the force acting on a body as measured in its rest frame, and τ is the proper time of the body, the time measured by a clock in its rest frame. This equation agrees with the Newtonian form in the low velocity limit as required by the correspondence principle. Moreover it is covariant under Lorentz transformations; if this law holds in one reference frame, then it holds in all reference frames.

The relativistic momentum p=mγc is the spatial part of p, the energy-momentum Minkowski vector and therefore F must also be the spatial part of a Minkowski vector, F. The full covariant relativistic version of Newton's second law must include the full four vectors:


Here we have the momentum-energy Minkowski vector


which satisfies

p2 = m2c2
from which we may infer


In the particle's rest frame, the momentum is (mc,0) and so for the force four-vector to be orthogonal, its time component must be zero in the rest frame as well, so F = (0,F). Applying a Lorentz transformation to an arbitrary frame, we find


Thus the time component of the relativistic version of Newton's second law is


Recalling the definition of work done by the applied force as


and since the change in energy is given by the work done, we have


and so finally we see that, up to an additive constant,

E = mγc2.
The energy is only defined up to an additive constant, so it is conceivable that we could define the total energy of a free particle to be given simply by the kinetic energy T = mc2(γ – 1) which differs from E by a constant, which is afterall the case in nonrelativistic mechanics. To see that the rest energy must be included, the law of conservation of momentum (which will serve as the relativistic replacement for Newton's third law) must be invoked, which dictates that the quantity mγc2 = mc2 + T be conserved and allows that rest energy can be converted into kinetic energy and vice versa, a phenomenon that is observed in many experiments.

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See also
Celeritas for the origins of using the c notation in E=mc².
Energy-momentum relation
Inertia
Mass-energy equivalence
Mass, momentum, and energy
Relativistic mass