In order to answer this question, we need to know the amount of matter that was converted into energy in the nuclear reaction. This can be calculated by using the equation E = mc^2, where E is the amount of energy released, m is the mass of the matter converted into energy, and c is the speed of light.
Using the equation, we can calculate that the mass of the matter converted into energy in the nuclear reaction is 0.1 kg. This means that the nuclear reaction converted 0.1 kg of matter into energy.
Other related questions:
Q: How do you calculate nuclear reactions?
A: There is no definitive answer to this question as there are many ways to calculate nuclear reactions, depending on the specific parameters involved. Some common methods include using the nuclear equation of state, statistical model calculations, or direct experimental measurements.
Q: How much energy will be created if 1.0 g of matter is destroyed completely how much kilowatt hour energy will be obtained by it?
A: If 1.0 g of matter is destroyed completely, the resulting energy would be approximately 9.0 x 10^15 joules, or 2.5 x 10^6 kilowatt hours.
Q: What is the equation that gives the amount of energy produced when matter is changed into energy in a nuclear process?
A: In a nuclear process, the amount of energy produced when matter is changed into energy is given by the equation:
E = mc2
where m is the mass of the matter and c is the speed of light.
Q: How do you calculate energy released in nuclear fusion?
A: The energy released in nuclear fusion can be calculated using the following equation:
E = m * c^2
Where:
E = Energy released (in joules)
m = Mass of the reactants (in kilograms)
c = Speed of light (in meters per second)