Radioactivity is a phenomenon in which a few substances spontaneously release energy and subatomic particles. The nuclear instability of an atom causes radioactivity.

(a) The number of nuclei is computed using the formula \(N = \frac{m}{M}{N_A}\)

Where \({\rm{m}}\) is the mass of \({}^{{\rm{226}}}{\rm{Ra}}\), \({\rm{M}}\)is the molar mass of \({}^{{\rm{226}}}{\rm{Ra}}\), and \({{\rm{N}}_{\rm{A}}}\)is the Avogadro number, the number of atoms may be computed as follows,

\(\begin{array}{c}N = (1.00\,{\rm{g}})\left( {\frac{{{\rm{mol}}}}{{226\,{\rm{g}}}}} \right)\frac{{6.022 \times {{10}^{23}}\,{\rm{atoms}}}}{{{\rm{mol}}}}\\ = 2.6646 \times {10^{21}}\,{\rm{atoms}}\end{array}\)

By the equation \(R = \frac{{0.693}}{{{t_{1/2}}}}\), where we know that \({}^{{\rm{226}}}{\rm{Ra}}\) has a half-life of \(1.6 \times {10^3}\,{\rm{y}}\).

\(\begin{array}{c}R = \frac{{\left( {0.693} \right)\left( {2.6646 \times {{10}^{21}}} \right)}}{{1.6 \times {{10}^3}\,{\rm{y}}}} \times \frac{{1\,{\rm{y}}}}{{3.156 \times {{10}^7}\,{\rm{s}}}}\\ = 3.66 \times {10^{10}}\,{\rm{Bq}}\left( {\frac{{1\,{\rm{Ci}}}}{{3.70 \times {{10}^{10}}\,{\rm{Bq}}}}} \right)\\ = 0.989\,{\rm{Ci}}\end{array}\)

Therefore, the activity \({\rm{R}}\) is \(0.989\,{\rm{Ci}}\).

(b) We now have a better understanding of the half-life of\({}^{{\rm{226}}}{\rm{Ra}}\) than we had when the\({\rm{Ci}}\) unit was first established.