What amount of energy is released in the fission of ${}_{92}U^{235}$ ?

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Solution

Fission:
Nuclear fission is the process by which an atom's nucleus breaks into multiple smaller nuclei.
Even by radioactive decay's energetic standards, the fission process frequently produces gamma photons and releases a considerable quantity of energy.

Fission of ${}_{92}U^{235}$ :
$n + {}_{92}^{235}U \to {}_{36}^{92}{Kr} + {}_{56}^{141}{Ba} + 3 n$
Step 1: analyzing the values
$energy released = Q = ∆ {mc}^{2}$
$1 MeV = 1.609 x 10^{- 13} J$
$m_{n} (mass of neutron) = 1.00865 u m_{u} (mass of uranium) = 235.0439 u m_{k} (mass of Kr) = 91.92616 u m_{b} (mass of barium) = 140.9144 u$
Step 2:Finding mass defect:

$∆ m = (m_{u} + m_{n} - m_{k} - m_{b} - 3 \times m_{n}) ∆ m = 235 + 1 - 95 - 139 - 3 \times 1 ∆ m = 0.1859 u 1 u = 1.66 \times 10^{- 27} kg so ∆ m = 3.09 \times 10^{- 28} kg$
Step 3: finding energy released
$Q = (m_{u} + m_{n} - m_{k} - m_{b} - 3 \times m_{n}) {(3 \times 10^{9})}^{2}$
$Q = (3.09 \times 10^{- 28}) {(3 \times 10^{9})}^{2} J$
$Q = 2.78 \times 10^{- 11} J$
$For one mole of {}_{92}^{235}U = 2.78 \times 10^{- 11} \times 6.022 \times 10^{23} = 1.67 \times 10^{10} kJ {mol}^{- 1} = 1.67 \times 10^{13} J {mol}^{- 1}$

So energy released in the fission of one mole of ${}_{92}U^{235}$ is $1.67 \times 10^{13} J {mol}^{- 1}$

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