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When two atoms or matter and antimatter eliminate each other, there is a massive energy output. This is calculated using the most famous equation E=mc2. "Energy" equal the total "mass" of both atoms multiplied by c (the speed of light) squared.
The famous equation is basically saying that mass is just a condensed form of energy. The 'c' part of the equation (the speed of light) is just the exchange rate (so to speak). For example, if we want to know how much energy we could make if we completely annihilated 1 kg of a substance, we can substitute our values into his equation. e=mc^2 e= 1 (c^2) e=c^2. So in 1kg of a substance, there are c squared joules of energy in it. This is a huge number, around 9*10^16. This number is 9 with 15 zeros after it!. So, why don't we use it to power nuclear stations? The reason is because one of the easiest ways of completely annihilating something is by mixing it with it's antimatter counterpart, which is unfortunately immensely difficult to synthesise in practical quantities.
e=mc^2 pretty much is a relation between mass (m) and energy (e) where c = speed of light. Pretty much, as something goes faster, it gains slightly more mass. It really has no visible effect when you're going like 60 mph, but when you go the speed of light the mass becomes almost infinite. We would have to generate an infinite amount of energy to propel this thing (which is pretty much impossible) so we can never really go the speed of light. Light travels at the top speed in the universe, but it's still finite. The equation ends up being: (c=mc^2) divide by c so that (1=mc) so the mass is very small.
This is a tricky question. Quantum mechanicss shows us that all energy can be turned into mass and all mass into energy. To work out the equivilant mass of an amount of energy (or vice versa) simply use einsteins famous equation E= mc^2 - rearrange m = E/c^2 I do not know of any device that can directly "weigh energy".
E=MC2 is the formula for the amount of energy (E) derived from a certain mass (M) times the speed of light squared (C2). The speed of light is a huge number, and multiplying it by itself results in an unimaginably higher number. Hence, the energy resulting from the formula is likewise huge.
Einstein's famous equation E=mc^2, states that, energy is the equivalent of mass multiplied by the square of the velocity of light, showing that a small amount of mass may be converted into a large number of energy and vice versa. stupid ahh hoe eat ahh and kick roCxs
Very much so. The incorrect ones never became famous.
For his famous equation of: E = MC squared
Scientists used it to develop Nuclear Power
Small problems quickly multiplied as each new part of the computer program was introduced. In the famous equation by Einstein, mass is multiplied by the speed of light squared, a very large value.
E = mc2 is Albert Einstein's famous equation
That equation is the equation that Albert Einstein came up with to describe how to calculate the speed of light. E = energy m = mass c = speed of light
e=mc squared the energy mass equivalence formula.
Temperature is a measure of how much energy an object has. Einstein's famous equation states the relationship your asking about; E=mc2. That is, the amount of energy an object has is proportional to its mass multiplied by the speed of light squared.
E=mc^2 states that mass and energy are interchangeable, and that a little bit of mass creates a lot of energy.
relativity
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