Formula: Fermi Distribution Function

$$P(W) ~=~ \frac{1}{\mathrm{e}^{ \frac{ W - \mu }{ k_{\text B} \, T}} ~+~ 1}$$ $$P(W) ~=~ \frac{1}{\mathrm{e}^{ \frac{ W - \mu }{ k_{\text B} \, T}} ~+~ 1}$$ $$W ~=~ k_{\text B} \, T \, \ln\left( \frac{1}{P(W)} ~-~ 1\right) ~+~ \mu$$ $$\mu ~=~ W ~-~ k_{\text B} \, T \, \ln\left( \frac{1}{P(W)} ~-~ 1\right)$$ $$T ~=~ \frac{ W ~-~ \mu }{ k_{\text B} \, \ln\left( \frac{1}{P(W)} ~-~ 1\right) }$$

Rearrange formula

Probability

$$ P(W) $$ Unit $$ - $$

The occupation probability indicates the probability $P$ that a state with energy $ W $ is occupied at temperature $ T $. At absolute zero ($T=0 \, \text{K}$), the probability that the state with energy $ W $ is occupied is exactly 50%: $ P(W) ~=~ \frac{1}{2}$.

Energy

$$ W $$ Unit $$ \mathrm{J} = \mathrm{Nm} = \frac{ \mathrm{kg} \, \mathrm{m^2} }{ \mathrm{s}^2 } $$

Energy state which can be occupied by a fermion, for example by an electron.

Chemical potential

$$ \mu $$ Unit $$ \mathrm{J} $$

Chemical potential gives the change of the internal energy when the particle number of the Fermi gas (e.g. free electron gas) changes. At $ T=0 \, \text{K} $ the chemical potential correspons to the Fermi energy: $ \mu = W_{\text F} $.

Temperature

$$ T $$ Unit $$ \mathrm{K} $$

Absolute temperature of the Fermi gas, for example a free electron gas in a metal.

Boltzmann Constant

$$ k_{\text B} $$ Unit $$ \frac{\mathrm J}{\mathrm K} = \frac{\mathrm{kg} \,\mathrm{m}^2}{\mathrm{s}^2 \, \mathrm{K}} $$

Boltzmann constant is a physical constant from many-particle physics and has the following exact value: $$ k_{\text B} ~=~ 1.380 \, 649 ~\cdot~ 10^{-23} \, \frac{\mathrm{J}}{\mathrm{K}} $$