m = E/c^2
The exact opposite of E=mc^2 would be E=(-mc)^2. In real world terms, -c^2 would have no physical significance because it is not a valid measurement or quantity. It is a mathematical manipulation of the original equation.
Albert Einstein announced the equation E=mc^2 in 1905 as part of his special theory of relativity.
Albert Einstein developed the equation E=mc^2 in 1905 as part of his theory of special relativity. This equation relates energy (E) to mass (m) and the speed of light (c).
The equation "FG = mc^2" is not a standard physics equation. "E=mc^2" (energy equals mass times the speed of light squared) is a famous equation from Einstein's theory of relativity that relates energy, mass, and the speed of light. If "FG" refers to a force, then the equation "FG = mc^2" doesn't have a standard interpretation in physics.
E = energy energy = mass X velocity of light squared The common form of the equation in conventional units is E = mc^2, but in relativistic units (where the speed of light c is 1) the equation reduces to just E = m which is much easier to calculate. The factor c^2 is just a units conversion constant.
The exact opposite of E=mc^2 would be E=(-mc)^2. In real world terms, -c^2 would have no physical significance because it is not a valid measurement or quantity. It is a mathematical manipulation of the original equation.
Mass.
The correct formula is E = MC².
C is the speed of light.
e=mc^2? e/c^2 = m
He did not use any databases to come up with E=mc^2.
Albert Einstein announced the equation E=mc^2 in 1905 as part of his special theory of relativity.
The theory of relativity can help you but not with the equation E=mc^2 E=mc^2 is just a conversion between mass and energy.
M = mass
E=mc^2 is born because of special relativity.
Albert Einstein.
Yes.