Einstein's equation in it's simplest form is E=mc2
so to get 9*1016 J divide this by c2 which would give you the mass
'which in this case is 1, In these units I believe this is 1kg
E=mc^2 (apex)
Energy balance can be described by this equation : Energy intake = internal heat produced + external work + energy stored.
The equation, E = mc2, is important today because it is the basic equation of nuclear physics. So for example it is used to calculate the amount of energy produced by the fuel in a nuclear power station, or the amount of energy potentially released in a hydrogen bomb. It is also important is astrophysical models of stars, where energy is provided by nuclear fusion. The equation is used alot in particle physics to calculate the masses of particles produced and to calculate the the energy needed to produce particular particles.
The matter of the astronaut causes the antimatter to anhilate each other, creating energy close to the energy produced by the equation E=mc2.
As well as the oft repeated E=MC2, Einstein also produced advances in the photoelectric effect (for which he received the Nobel prize), Brownian motion, and in relativity both special and general. He was also quite active in cosmology, and predicted gravitational lensing. (Bending of light as it passes a star). He also had theories on special and general relativity.
E = M c2M = (E) / (c2)M = (9 x 1016) / (3 x 108)2= (9 x 1016) / (9 x 1016)= 1 kgAmazing. That's a lotta energy. Like 2.85 gigawatt-years, according to my Casio !
it is the food that is produced in plants
Carbon dioxide, according to the ionic equation CO3-2 + 2 H+1 -> CO2 + H2O.
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whatis the word equation of Iron oxide when metal oxide is added and what gas is produced in the reaction
Albert Einstein
In the equation N2+3H2=2NH3, the amount of ammonia produced from 50g of N would be 16.667g.
228.8 g of CO2 228.8 g
1.2 Moles
1.2 Moles
2,25 H2 moles