In a nuclear reactor, 235U undergoes Fission liberating 200 MeV of energy. The reactor has a 10 % efficiency and produces 1000 MW power. If the reactor is to function for 10 yr , find the total mass of uranium required.

Question

In a nuclear reactor, 235U undergoes Fission liberating 200 MeV of energy. The reactor has a 10 % efficiency and produces 1000 MW power. If the reactor is to function for 10 yr , find the total mass of uranium required. (A) 38470 (B) 38490 (C) 48490 (D) 48470

Tardigrade Admin · Accepted Answer

The reactor produces 1000 MW power or 109J/s. The reactor is to function for 10 yr. Therefore, total energy which the reactor will supply in 10 yr is
E = (power) (time)
= (10⁹J/s) (10 x 365 x 24 x 3600s)
= 3. 1536 x 10¹⁷ J
But since the efficiency of the reactor is only 10%, therefore actual energy needed is 10 times of it or 3. 1536 x

1 0^{18}

J. One uranium atom liberates 200 MeV of energy or 200 x 1. 6 x

1 0^{- 13}

J or 3. 2 x

1 0^{- 11}

J of energy. So, number of uranium atoms needed are

\frac{3.1536 \times 1 0 ^{18}}{3.2 \times 1 0 ^{- 11}} = 0.9855 \times 1 0^{29}

or number of kg - moles of uranium needed are

n = \frac{0.9855 \times 1 0 ^{29}}{6.02 \times 1 0 ^{26}} = 163.7

Hence, total mass of uranium required is
m = (n)M
or = (163. 7) (235) kg
or m = 38470 kg
or m = 38470 kg

Q. In a nuclear reactor, _235U undergoes Fission liberating 200MeV of energy. The reactor has a 10% efficiency and produces 1000MW power. If the reactor is to function for 10yr , find the total mass of uranium required.

38470

38490

48490

48470

Q. In a nuclear reactor, $_^{235} U$ undergoes Fission liberating $200 M e V$ of energy. The reactor has a $10%$ efficiency and produces $1000 M W$ power. If the reactor is to function for $10 yr$ , find the total mass of uranium required.