In a nuclear reactor, the mass converted to energy takes place at a rate of $70 \mathrm{\mu g} {\mathrm{s}}^{-1}$. Calculate the maximum power output from the reactor assuming that it is $100\%$ efficient.

The equation shows the radioactive decay of radon-$222$.

 ${}_{86}{}^{222}\mathrm{Rn}\to {}_{84}{}^{218}\mathrm{Po}+{}_2{}^4\alpha +\gamma$

Calculate the total energy output from this decay and state what forms of energy are produced.

(Mass of ${}_{86}{}^{222}\mathrm{Rn}=221.970\mathrm{u}$, mass of ${}_{84}{}^{222}\mathrm{Po}=217.963\mathrm{u}$, mass of ${}_2{}^4\alpha =4.002\mathrm{u},1\mathrm{u}$ is the unified atomic mass unit $\left.=1.660\times {10}^{-27} \mathrm{kg}.\right)$

A carbon-12 atom consists of six protons, six neutrons and six electrons. The unified atomic mass unit $\left(\mathrm{u}\right)$ is defined as $\frac{1}{12}$ the mass of the carbon-12 atom. Calculate:

(a) the mass defect in kilograms

 (Mass of a proton $=1.007276\mathrm{u}$, mass of a neutron $=1.008665\mathrm{u}$, mass of an electron $=0.000548\mathrm{u}$.)

A carbon-12 atom consists of six protons, six neutrons and six electrons. The unified atomic mass unit $\left(\mathrm{u}\right)$ is defined as $\frac{1}{12}$ the mass of the carbon-12 atom. Calculate:

(b) the binding energy

 (Mass of a proton $=1.007276\mathrm{u}$, mass of a neutron $=1.008665\mathrm{u}$, mass of an electron $=0.000548\mathrm{u}$.)

A carbon-12 atom consists of six protons, six neutrons and six electrons. The unified atomic mass unit $\left(\mathrm{u}\right)$ is defined as $\frac{1}{12}$ the mass of the carbon-12 atom. Calculate:

(c) the binding energy per nucleon.

 (Mass of a proton $=1.007276\mathrm{u}$, mass of a neutron $=1.008665\mathrm{u}$, mass of an electron $=0.000548\mathrm{u}$.)

The fusion reaction that holds most promise for the generation of electricity is the fusion of tritium ${}_1{}^3\mathrm{H}$ and deuterium ${}_1{}^2\mathrm{H}$.

The following equation shows the process: ${}_1{}^3\mathrm{H}+{}_1{}^2\mathrm{H}\to {}_2{}^4\mathrm{He}+{}_1{}^1\mathrm{H}$

Calculate:

(a) the change in mass in the reaction

(Mass of ${}_1{}^3\mathrm{H}=3.015500\mathrm{u}$, Mass of ${}_1{}^2\mathrm{H}=2.013553\mathrm{u}$, Mass of ${}_2{}^4\mathrm{He}=4.00150\mathrm{u}$, Mass of ${}_1{}^1\mathrm{H}=1.007276\mathrm{u}.$ )

The fusion reaction that holds most promise for the generation of electricity is the fusion of tritium ${}_1{}^3\mathrm{H}$ and deuterium ${}_1{}^2\mathrm{H}$.

The following equation shows the process: ${}_1{}^3\mathrm{H}+{}_1{}^2\mathrm{H}\to {}_2{}^4\mathrm{He}+{}_1{}^1\mathrm{H}$

Calculate:

(b) the energy released in the reaction

(Mass of ${}_1{}^3\mathrm{H}=3.015500\mathrm{u}$, Mass of ${}_1{}^2\mathrm{H}=2.013553\mathrm{u}$, Mass of ${}_2{}^4\mathrm{He}=4.00150\mathrm{u}$, Mass of ${}_1{}^1\mathrm{H}=1.007276\mathrm{u}.$ )

The fusion reaction that holds most promise for the generation of electricity is the fusion of tritium ${}_1{}^3\mathrm{H}$ and deuterium ${}_1{}^2\mathrm{H}$. The following equation shows the process: ${}_1{}^3\mathrm{H}+{}_1{}^2\mathrm{H}\to {}_2{}^4\mathrm{He}+{}_1{}^1\mathrm{H}$

Calculate:

(c) the energy released if one mole of deuterium were reacted with one mole of tritium.

(Mass of ${}_1{}^3\mathrm{H}=3.015500\mathrm{u}$, mass of ${}_1{}^2\mathrm{H}=2.013553\mathrm{u}$, mass of ${}_2{}^4\mathrm{He}=4.00150\mathrm{u};$ mass of ${}_1{}^1\mathrm{H}=1.007276\mathrm{u}.$ )

The initial activity a sample of 1 mole of radon-220 is $8.02\times {10}^{21}{ \mathrm{s}}^{-1}$.

Calculate:

(a) the decay constant for this isotope.