91Ó°ÊÓ

a) Fermi energy of aluminum,$E_F=11.6 eV$

b) Density of aluminum,$d=2.7 \mathrm{g}/{\mathrm{cm}}^3$

c) Molar mass of aluminum,$A=27 \mathrm{g}/\mathrm{mol}$

The electrons that jump from the valence band to the conduction band, by absorbing energy from the surrounding, are called conduction electrons. These electrons are now free to move within the walls of the sample of a substance.

Formulae:

The Energy of Fermi level of a metal,$E_F=A{n}^{2/3}  â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots \left(1\right)$

where, is the number density of conduction electrons and$A=3.65×{10}^{-19} m^{2}eV$

The number of atoms per unit volume,$N=d/M  â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots \left(2\right)$

Where, d = density and M is the mass per atom$M=A/N_Aâ‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots â‹\dots \left(3\right)$

The mass of a substance per atom,

$where{N}_A=6.022×{10}^{23} /mol$and A is the molar mass.

LetN be the number of atoms per unit volume and n be the number of conduction electrons per unit volume.

At first, the number of conduction electrons per unit volume of aluminum can be calculated using equation as follows:

$$\begin{gathered} n={\left(\frac{E_F}{A}\right)}^{3/2} \\ ={\left(\frac{11.6eV}{3.65×{10}^{-19}{m}^{2}eV}\right)}^{3/2} \\ =1.79×{10}^{29}{m}^{-3}........................\left(a\right) \end{gathered}$$

Now, the mass of aluminum per atom can be calculated using equation and the given data, as follows:

$$\begin{gathered} M=\frac{27g/mol}{6.022×{10}^{23}/mol} \\ =4.48×{10}^{-23}g \end{gathered}$$

Now, using this mass value in equation , we can get the value of the number of atoms per unit volume as follows:

$$\begin{gathered} N=\frac{2.7g/c{m}^3}{4.48×0^{-23}g} \\ =6.03×{10}^{22}/c{m}^3 \\ =6.03×{10}^{28}/m^3.............................\left(b\right) \end{gathered}$$

Now, the number of conduction electrons per atom can be calculated by dividing equation (a) by equation (b) as follows:

$$\begin{gathered} \frac{n}{N}=\frac{1.79×{10}^{29}{m}^{-3}}{6.03×{10}^{28}/m^3} \\ =2.97 \\ ≈3 \end{gathered}$$

Hence, the required number of conduction electrons per atom is 3.