Boltzmann factor: Difference between revisions

In physics, the Boltzmann factor is a weighting factor that determines the relative probability of a particle to be in a state ${\displaystyle i}$ in a multi-state system in thermodynamic equilibrium at temperature ${\displaystyle T}$. The Boltzmann factor is normally used when discussing systems described by the canonical ensemble - for the grand canonical ensemble, it is more appropriate to use the Gibbs' factor which takes into account particle transfer between the system and the environment.

The probability that a system is in a state ${\displaystyle E_{i}}$ is given by:

${\displaystyle P(E_{i})={\frac {1}{Z}}\exp {(-\beta E_{i}\,)}}$

Where ${\displaystyle \beta }$ is given by

${\displaystyle \beta ={\frac {1}{k_{B}T}}}$

${\displaystyle Z_{}}$ is the Partition Function, ${\displaystyle k_{B}}$ is Boltzmann's Constant, ${\displaystyle T}$ is temperature and ${\displaystyle E_{i}}$ is the energy of state ${\displaystyle i}$.

The Boltzmann factor is the term:

${\displaystyle \exp {(-\beta E_{i}\,)}=\exp {(-E_{i}/k_{B}T)}}$

Derivation

Consider a single atom system with energy states ${\displaystyle E_{1},E_{2},...}$. The system is in contact with a heat reservoir and thus conservation of energy gives total energy

${\displaystyle E=E_{s}+E_{r}=const}$

with ${\displaystyle E_{s}}$ being total system energy and ${\displaystyle E_{r}}$ being total reservoir energy. In equilibrium, the number of states in ${\displaystyle R}$ and ${\displaystyle S}$ is the multiplicity ${\displaystyle \Omega }$. Similar to total energy, we can write:

${\displaystyle \Omega _{E}\approx \Omega _{R}(E_{R})\Omega _{S}(E_{S})}$

The probability that an atom is in state ${\displaystyle E_{j}}$ is related to the number of states in the reservoir - from Equipartition theorem. Consider taking the ratio of two probabilities:

${\displaystyle {\frac {P(E_{2})}{P(E_{1})}}={\frac {\Omega _{R}(E-E_{2})}{\Omega _{R}(E-E_{1})}}}$

We can relate the number of states to the entropy via

${\displaystyle S_{R}(E_{j})=k_{B}\ln[\Omega _{R}(E-E_{j})]}$

giving:

${\displaystyle {\frac {P(E_{2})}{P(E_{1})}}={\frac {\exp {[{\frac {S_{R}(E_{2})}{k_{B}}}]}}{\exp {[{\frac {S_{R}(E_{1})}{k_{B}}}]}}}=\exp \left[{\frac {S_{R}(E_{2})-S_{R}(E_{1})}{k_{B}}}\right]}$

The Fundamental thermodynamic relation tells us that for the reservoir (rearranging and neglecting the chemical potential term):

${\displaystyle dS_{R}={\frac {1}{T}}[dU_{R}+PdV_{R}]}$

Where ${\displaystyle S_{R}}$ is the entropy, ${\displaystyle U_{R}}$ is the internal energy, ${\displaystyle P}$ is pressure and ${\displaystyle V}$ is volume.

For a gas, it is reasonable to assume that ${\displaystyle PdV_{R}\ll dU_{R}}$ so this term also drops out giving:

${\displaystyle \Delta S_{R}={\frac {1}{T}}\Delta U_{R}}$

${\displaystyle \Delta S_{R}={\frac {1}{T}}[U_{R}(E_{2})-U_{R}(E_{1})]}$

By energy conservation ${\displaystyle E=E_{R}+E_{i}}$ and ${\displaystyle U_{R}(E_{j})=E-E_{j}}$ giving

${\displaystyle \Delta S_{R}=-{\frac {1}{T}}(E_{1}-E_{2})}$

Substituting into the probability ratio gives:

${\displaystyle {\frac {P(E_{2})}{P(E_{1})}}=\exp({\frac {-[E_{2}-E_{1}]}{k_{B}T}})={\frac {\exp {(-\beta E_{2})}}{\exp {(-\beta E_{1})}}}}$

Where we have defined an arbitrary symbol ${\displaystyle \beta }$, which is the reciprocal of Boltzmann's constant times temperature. Through separation of variables, we can write

${\displaystyle {\frac {P(E_{2})}{\exp {(-\beta E_{2})}}}={\frac {P(E_{1})}{\exp {(-\beta E_{1})}}}=const={\frac {1}{Z}}}$

and hence

${\displaystyle P(E_{i})={\frac {1}{Z}}\exp {(-\beta E_{i})}}$

Notes

The Boltzmann factor is not a probability by itself, because it is not normalized. The normalization factor is one divided by the partition function, the sum of the Boltzmann factors for all states of the system. This gives the Boltzmann distribution.

From the Boltzmann factor it is possible to derive the Maxwell-Boltzmann statistics, Bose-Einstein statistics, and Fermi-Dirac statistics that govern classical particles as wrtber ny4 n7edn76ell as quantum mechanical bosons, and fermions, respectively.

See also

• Boltzmann relation (plasma physics)

References

• Charles Kittel and Herbert Kroemer, Thermal Physics, 2nd ed. (Freeman & Co.: New York, 1980).