363717 ${10}^{14}$ fissions per second are taking place in a nuclear reactor having efficiency $40\mathrm{\%}$. The energy released per fission is $250MeV$. The power output of the reactor is

363718 Consider the nuclear fission reaction ${}_0^{1}n+{}_{92}^{235}U\to {}_{56}^{144}Ba+{}_{36}^{89}Kr+3{}_0^{1}n$. Assuming all the kinetic energy is carried away by the fast neutrons only and total binding energies of ${}_{92}^{235}U,{}_{56}^{144}Ba$, and ${}_{36}^{89}Kr$ to be $1800MeV$, $1200MeV$ and $780MeV$ respectively, the average kinetic energy carried by each fast neutron is (in $MeV$)

363719 In a fission reaction ${}_{92}^{236}U{\to }^{117}X{+}^{117}Y+n+n,$ the average binding energy per nucleon of $X$ and $Y$ is $8.5MeV$ whereas that of ${}^{236}U$ is $7.6MeV$.
The total energy liberated will be about :
${}_{92}^{236}U\to {}^{117}X+{}^{117}Y+n+n$

363720 Which of the following nuclear fragments corresponding to nuclear fission between neutron $\left({}_0^{1}n\right)$ and uranium isotope $\left({}_{92}^{235}U\right)$ is correct?

363717 ${10}^{14}$ fissions per second are taking place in a nuclear reactor having efficiency $40\mathrm{\%}$. The energy released per fission is $250MeV$. The power output of the reactor is

363718 Consider the nuclear fission reaction ${}_0^{1}n+{}_{92}^{235}U\to {}_{56}^{144}Ba+{}_{36}^{89}Kr+3{}_0^{1}n$. Assuming all the kinetic energy is carried away by the fast neutrons only and total binding energies of ${}_{92}^{235}U,{}_{56}^{144}Ba$, and ${}_{36}^{89}Kr$ to be $1800MeV$, $1200MeV$ and $780MeV$ respectively, the average kinetic energy carried by each fast neutron is (in $MeV$)

363719 In a fission reaction ${}_{92}^{236}U{\to }^{117}X{+}^{117}Y+n+n,$ the average binding energy per nucleon of $X$ and $Y$ is $8.5MeV$ whereas that of ${}^{236}U$ is $7.6MeV$.
The total energy liberated will be about :
${}_{92}^{236}U\to {}^{117}X+{}^{117}Y+n+n$

363720 Which of the following nuclear fragments corresponding to nuclear fission between neutron $\left({}_0^{1}n\right)$ and uranium isotope $\left({}_{92}^{235}U\right)$ is correct?

363717 ${10}^{14}$ fissions per second are taking place in a nuclear reactor having efficiency $40\mathrm{\%}$. The energy released per fission is $250MeV$. The power output of the reactor is

363718 Consider the nuclear fission reaction ${}_0^{1}n+{}_{92}^{235}U\to {}_{56}^{144}Ba+{}_{36}^{89}Kr+3{}_0^{1}n$. Assuming all the kinetic energy is carried away by the fast neutrons only and total binding energies of ${}_{92}^{235}U,{}_{56}^{144}Ba$, and ${}_{36}^{89}Kr$ to be $1800MeV$, $1200MeV$ and $780MeV$ respectively, the average kinetic energy carried by each fast neutron is (in $MeV$)

363719 In a fission reaction ${}_{92}^{236}U{\to }^{117}X{+}^{117}Y+n+n,$ the average binding energy per nucleon of $X$ and $Y$ is $8.5MeV$ whereas that of ${}^{236}U$ is $7.6MeV$.
The total energy liberated will be about :
${}_{92}^{236}U\to {}^{117}X+{}^{117}Y+n+n$

363720 Which of the following nuclear fragments corresponding to nuclear fission between neutron $\left({}_0^{1}n\right)$ and uranium isotope $\left({}_{92}^{235}U\right)$ is correct?

363717 ${10}^{14}$ fissions per second are taking place in a nuclear reactor having efficiency $40\mathrm{\%}$. The energy released per fission is $250MeV$. The power output of the reactor is

363718 Consider the nuclear fission reaction ${}_0^{1}n+{}_{92}^{235}U\to {}_{56}^{144}Ba+{}_{36}^{89}Kr+3{}_0^{1}n$. Assuming all the kinetic energy is carried away by the fast neutrons only and total binding energies of ${}_{92}^{235}U,{}_{56}^{144}Ba$, and ${}_{36}^{89}Kr$ to be $1800MeV$, $1200MeV$ and $780MeV$ respectively, the average kinetic energy carried by each fast neutron is (in $MeV$)

363719 In a fission reaction ${}_{92}^{236}U{\to }^{117}X{+}^{117}Y+n+n,$ the average binding energy per nucleon of $X$ and $Y$ is $8.5MeV$ whereas that of ${}^{236}U$ is $7.6MeV$.
The total energy liberated will be about :
${}_{92}^{236}U\to {}^{117}X+{}^{117}Y+n+n$

363720 Which of the following nuclear fragments corresponding to nuclear fission between neutron $\left({}_0^{1}n\right)$ and uranium isotope $\left({}_{92}^{235}U\right)$ is correct?