The spontaneous emission of radiation in the form of particles or high-energy photons as a result of a nuclear process is known as radioactivity.

\({E_{ion}} = 30\,{\rm{eV}}\)

The energy of the radiation in the Geiger tube is given as: \({E_{rad}} = 1.0\,{\rm{MeV}}\).

The number of ion pairs, is then obtained as:

\(\begin{align}Number{\rm{ }}of{\rm{ }}ion{\rm{ }}pairs(N) &= \frac{{The{\rm{ }}energy{\rm{ }}of{\rm{ }}the{\rm{ }}radiation{\rm{ }}in{\rm{ }}the{\rm{ }}Geiger{\rm{ }}tube}}{{The{\rm{ }}energy{\rm{ }}for{\rm{ }}ionize{\rm{ }}molecule}}\\ &= \frac{{1.0 \times {{10}^6}\,eV}}{{30\,eV}}\\ &= 3.333 \times {10^4}\,pairs\end{align}\)

The following relation is used to evaluate the current as:

\(\begin{align}I &= \frac{Q}{{\Delta t}}\\ &= \frac{{2N{\rm{ }}e}}{{\Delta t}}\end{align}\)

Substitute all the value in the above equation

\(\begin{align}I &= \frac{{2 \times 3.333 \times {{10}^4}\,pairs \times 1.6 \times {{10}^{ - 19}}\,C}}{{1 \times {{10}^{ - 6}}\,s}}\\ &= 1.0666 \times {10^{ - 8}}\,A\end{align}\)

Therefore, the current is: \(1.0666 \times {10^{ - 8}}\,{\rm{A}}\).

\(\begin{align}{I_n} &= nI\\ &= 900\,ions \times 1.0666 \times {10^{ - 8}}\,A\\ &= 9.5994 \times {10^{ - 6}}\,A\end{align}\)

Therefore, current if last effect multiplies the number of ion pairs is: \(9.5994 \times {10^{ - 6}}\,{\rm{A}}\).