147968 If the energy released in the fission of one nucleus is $3.2 \times 10^{-11} \mathrm{~J}$. Then, the numbers of nuclei required per second in a power plant of $16 \mathrm{~kW}$ is (assume efficiency of plant $=1 \%$ )
#[Qdiff: Hard, QCat: Numerical Based, examname: UP CPMT-2001,AP EAMCET- 24 -09-2020] Shift - I
]#

147969 If radius of the ${ }_{13}^{27} \mathrm{Al}$ nucleus is taken to be $R_{\mathrm{A} I}$ then the radius of ${ }_{53}^{125} \mathrm{Te}$ nucleus is

147972 The energy released when one nucleus of ${ }_{92} \mathrm{U}^{235}$ undergoes fission is $188 \mathrm{MeV}$. The energy releases when $100 \mathrm{~g}$ of ${ }_{92} \mathrm{U}^{235}$ undergoes fission is

147976 In uranium radioactive series, initial nucleus ${ }^{238} U_{92}$ decays to final nucleus ${ }^{206} U_{82}$. In this process, the number of $\alpha$-particles and $\beta$ particles emitted are

147968 If the energy released in the fission of one nucleus is $3.2 \times 10^{-11} \mathrm{~J}$. Then, the numbers of nuclei required per second in a power plant of $16 \mathrm{~kW}$ is (assume efficiency of plant $=1 \%$ )
#[Qdiff: Hard, QCat: Numerical Based, examname: UP CPMT-2001,AP EAMCET- 24 -09-2020] Shift - I
]#

147969 If radius of the ${ }_{13}^{27} \mathrm{Al}$ nucleus is taken to be $R_{\mathrm{A} I}$ then the radius of ${ }_{53}^{125} \mathrm{Te}$ nucleus is

147972 The energy released when one nucleus of ${ }_{92} \mathrm{U}^{235}$ undergoes fission is $188 \mathrm{MeV}$. The energy releases when $100 \mathrm{~g}$ of ${ }_{92} \mathrm{U}^{235}$ undergoes fission is

147976 In uranium radioactive series, initial nucleus ${ }^{238} U_{92}$ decays to final nucleus ${ }^{206} U_{82}$. In this process, the number of $\alpha$-particles and $\beta$ particles emitted are

147968 If the energy released in the fission of one nucleus is $3.2 \times 10^{-11} \mathrm{~J}$. Then, the numbers of nuclei required per second in a power plant of $16 \mathrm{~kW}$ is (assume efficiency of plant $=1 \%$ )
#[Qdiff: Hard, QCat: Numerical Based, examname: UP CPMT-2001,AP EAMCET- 24 -09-2020] Shift - I
]#

147969 If radius of the ${ }_{13}^{27} \mathrm{Al}$ nucleus is taken to be $R_{\mathrm{A} I}$ then the radius of ${ }_{53}^{125} \mathrm{Te}$ nucleus is

147972 The energy released when one nucleus of ${ }_{92} \mathrm{U}^{235}$ undergoes fission is $188 \mathrm{MeV}$. The energy releases when $100 \mathrm{~g}$ of ${ }_{92} \mathrm{U}^{235}$ undergoes fission is

147976 In uranium radioactive series, initial nucleus ${ }^{238} U_{92}$ decays to final nucleus ${ }^{206} U_{82}$. In this process, the number of $\alpha$-particles and $\beta$ particles emitted are

147968 If the energy released in the fission of one nucleus is $3.2 \times 10^{-11} \mathrm{~J}$. Then, the numbers of nuclei required per second in a power plant of $16 \mathrm{~kW}$ is (assume efficiency of plant $=1 \%$ )
#[Qdiff: Hard, QCat: Numerical Based, examname: UP CPMT-2001,AP EAMCET- 24 -09-2020] Shift - I
]#

147969 If radius of the ${ }_{13}^{27} \mathrm{Al}$ nucleus is taken to be $R_{\mathrm{A} I}$ then the radius of ${ }_{53}^{125} \mathrm{Te}$ nucleus is

147972 The energy released when one nucleus of ${ }_{92} \mathrm{U}^{235}$ undergoes fission is $188 \mathrm{MeV}$. The energy releases when $100 \mathrm{~g}$ of ${ }_{92} \mathrm{U}^{235}$ undergoes fission is

147976 In uranium radioactive series, initial nucleus ${ }^{238} U_{92}$ decays to final nucleus ${ }^{206} U_{82}$. In this process, the number of $\alpha$-particles and $\beta$ particles emitted are