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In  classical [[statistical physics]], the '''Boltzmann distribution'''  expresses the  relative probability  that a subsystem  of a physical system has a certain [[energy]]. The subsystem must part of a physical system that is in thermal equilibrium, that is, the system must have a well-defined (absolute) [[temperature]]. For instance, a single [[molecule]] can be a subsystem of, say, one [[mole]] of [[ideal gas law|ideal gas]] and the Boltzmann distribution applies to the energies of the individual gas molecules, provided the total amount of the ideal gas is in thermal equilibrium.     
In  classical [[statistical physics]], the '''Boltzmann distribution'''  expresses the  relative probability  that a subsystem  of a physical system has a certain [[energy]]. The subsystem must part of a physical system that is in thermal equilibrium, that is, the system must have a well-defined (absolute) [[temperature]]. For instance, a subsystem can be a single [[molecule]] in, say, one [[mole]] of an [[ideal gas law|ideal gas]]. Then the Boltzmann distribution applies to the energies of the individual gas molecules, provided the ideal gas is in thermal equilibrium.     


The Boltzmann distribution (also known as the '''Maxwell-Boltzmann distribution''') was  proposed in 1859 by the Scotsman [[James Clerk Maxwell]] for the statistical distribution of the [[kinetic energy|kinetic energies]] of ideal gas molecules. The Maxwell-Boltzmann law can be formulated as the ratio of two numbers. Consider an ideal gas of temperature ''T''. Let ''n''<sub>1</sub> be the number of molecules with energy ''E''<sub>1</sub> and  ''n''<sub>2</sub> be the number  with energy ''E''<sub>2</sub>, then according to the Maxwell-Boltzmann distribution law,
The Boltzmann distribution (also known as the '''Maxwell-Boltzmann distribution''') was  proposed in 1859 by the Scotsman [[James Clerk Maxwell]] for the statistical distribution of the [[kinetic energy|kinetic energies]] of ideal gas molecules.   Consider an ideal gas of absolute temperature ''T''. Let ''n''<sub>1</sub> be the number of molecules with kinetic energy ''E''<sub>1</sub> and  ''n''<sub>2</sub> be the number  with kinetic energy ''E''<sub>2</sub>, then according to the Maxwell-Boltzmann distribution law the relative probability is the ratio,
:<math>
:<math>
\frac{n_1}{n_2} = \frac{e^{-E_1/(kT)}}{e^{-E_2/(kT)}},  \qquad\qquad \qquad\qquad (1)
\frac{n_1}{n_2} = \frac{e^{-E_1/(kT)}}{e^{-E_2/(kT)}},  \qquad\qquad \qquad\qquad (1)
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where ''k'' is the [[Boltzmann constant]]. Most noticeable in this expression are (i) the energy in an exponential, (ii) the inverse temperature in the exponent, and (iii) the appearance of the natural constant ''k''.  Note that an argument of an exponential must be dimensionless and that accordingly ''kT'' has the dimension energy.
where ''k'' is the [[Boltzmann constant]]. Most noticeable in this expression are (i) the energy in an exponential, (ii) the inverse temperature in the exponent, and (iii) the appearance of the natural constant ''k''.  Note that an argument of an exponential must be dimensionless and that accordingly ''kT'' has the dimension energy.


The molecular energies may, in addition to kinetic energies, contain interactions with an external field. For instance, if a system, as for instance a column of air, is in the [[gravitation|gravitational field]] of the Earth, each molecular energy may contain the additional term ''mgh'', where ''m'' is the molecular mass, ''g'' the [[gravitational  acceleration]] and ''h'' the height of the molecule above the surface of the Earth.
As discovered in 1871 by the Austrian [[Ludwig Boltzmann]], the molecular energies in equation (1) may, in addition to the translational energy considered by Maxwell, contain rotational and vibrational energies of the molecules. Also interactions with an external field may be included. If a system, as for instance a column of air of constant temperature (zero [[lapse rate]]), is in the [[gravitation|gravitational field]] of the Earth, each molecular energy contains the additional term ''mgh'', where ''m'' is the molecular mass, ''g'' the [[gravitational  acceleration]] and ''h'' the height of the molecule above the surface of the Earth. Thus, the ratio  of the number of molecules at height ''h''<sub>1</sub> and  ''h''<sub>2</sub> is,
 
:<math>
\frac{n(h_1)}{n(h_2)} = \frac{e^{-(E_1 +mgh_1)/(kT)}}{e^{-(E_2 +mgh_2)/(kT)}} 
\approx \exp\Big[ - \frac{mg(h_1-h_2)}{kT}\Big]  ,
</math>
where we made the assumption that the difference in molecular  kinetic energies at the two heights is small in comparison  to the difference in potential energies:
:''E''<sub>2</sub> &minus; ''E''<sub>1</sub> << ''mg''(''h''<sub>2</sub>&minus;''h''<sub>1</sub>),
so that the difference in kinetic energies may be omitted.
==Generalization==
==Generalization==
Maxwell's finding was generalized in 1871 by  the Austrian [[Ludwig Boltzmann]], who gave the energy distribution of gas molecules  having both kinetic ''and'' potential energies.  
A few years after Boltzmann,  the American [[Josiah Willard Gibbs]] gave a further formalization and generalization (ca. 1877).  Gibbs introduced what he called an ''ensemble'', a "supersystem"  consisting of a statistically large number of identical systems.  For instance, the systems may be identical vessels containing the same number of the same real gas molecules at the same temperature and pressure. Further Gibbs assumed that the ensemble, just like a system of gas molecules, is in thermal equilibrium, i.e., the systems are in thermal contact so that they can exchange [[heat]]. In the example that the systems are gas-filled vessels, this is achieved by requiring that the vessels are in mutual contact through heat-conducting walls.


A few years later (ca. 1877) the American [[Josiah Willard Gibbs]]  gave a further formalization and generalization.  Gibbs introduced an ''ensemble'' consisting of a statistically large number of identical subsystems.  For instance, the subsystems may  be identical vessels containing the same number ''N''  of the same real gas  molecules at the same temperature and pressure. Further Gibbs assumed that the ensemble, just like a system of gas molecules,  is in thermal equilibrium, i.e., the subsystems are in thermal contact so that they can exchange [[heat]]. For example, the subsystems may be gas-filled vessels with heat-conducting walls.   
Gibbs assumed<ref>To get the history correct: Gibbs made a few very fundamental assumptions from which he ''derived'' the equivalence of equation (1).</ref> that the Maxwell-Boltzmann law, equation (1), holds for the energies of the systems in the ensemble.  This generalization, applied to the example of an ensemble consisting of gas-filled vessels, means that the energy of a gas molecule in equation (1) is replaced by the total energy of the molecules in a vessel;  a "one-molecule" energy is promoted to a "one-vessel" energy.  Because of molecular interactions (that are absent in an ideal gas), a one-vessel energy  cannot be written as a sum of one-molecule energies. This is the main reason for Gibbs' generalization from a single vessel of gas to an ensemble of vessels, or, in more general terms, the generalization from an ideal gas to an ensemble of (rather arbitrary) systems. Just as the molecules in an ideal gas, the systems in the ensemble do not interact other than by exchanging heat.
 
Gibbs  assumed that the Maxwell-Boltzmann law, equation (1), holds for the energies of the subsystems in the ensemble.  In  this generalization&mdash;and the example of an ensemble consisting of gas-filled vessels&mdash;the energy of a single gas molecule is replaced by the energy of the ''N'' molecules in a single vessel;  a one-molecule energy is promoted to a one-vessel energy.  Because of molecular interactions (that are absent in an ideal gas), a one-vessel energy  cannot be written as a sum of one-molecule energies. This is the main reason for Gibbs' generalization of a single vessel of gas to an ensemble of vessels, or, in more general terms, the generalization from an ideal gas to an ensemble of (rather arbitrary) subsystems. Like the molecules in an ideal gas, the subsystems do not interact other than by exchanging heat.
   
   
The ''absolute'' probability for a subsystem to have  total energy ''E''<sub>''k''</sub> can be obtained from the ''relative'' probability [equation (1)] by normalizing the probability distribution. Let us assume, for convenience sake, that the one-subsystem energies are discrete (as they often are in [[quantum mechanics]]), then
The absolute probability for a system to have  total energy ''&epsilon;''<sub>''j''</sub> can be obtained from equation (1) by normalizing. Let us assume, for convenience sake, that the one-system energies are discrete (as they often are in [[quantum mechanics]]) running from &epsilon;<sub>0</sub> to &epsilon;<sub>&infin;</sub> , then
:<math>
:<math>
\mathcal{P}(E_k) = \frac{e^{-E_k/(kT)}}{Q} \quad \hbox{with} \quad Q \equiv \sum_{i=0}^\infty e^{-E_i/(kT)} .
N_j e^{-\epsilon_i/(kT)} = N_i  e^{-\epsilon_j/(kT)}  
\;\Longrightarrow\;
N_j \sum_{i=0}^\infty e^{-\epsilon_i/(kT)} =  e^{-\epsilon_j/(kT)} \sum_{i=0}^\infty N_i
</math>
</math>
This probability can be written as
which gives
:<math>
:<math>
\mathcal{P}(E_k) = \frac{M_k}{M}
\frac{N_j}{N} = \frac{e^{-\epsilon_j/(kT)}}{Q} \quad \hbox{with} \quad Q \equiv \sum_{i=0}^\infty  e^{-\epsilon_i/(kT)} \quad \hbox{and} \quad N =\sum_{i=0}^\infty N_i ,
</math>
</math>
where ''M''<sub>''k''</sub> is the number of subsystems that have energy ''E''<sub>''k''</sub> and ''M'' is the total number of subsystems in the ensemble (''M'' must be large, say on the order of [[Avogadro's number]] for statistics to apply).  
where ''N''<sub>''j''</sub> is the number of systems that have energy ''&epsilon;''<sub>''j''</sub> and ''N'' is the total number of systems in the ensemble (''N'' must be very large&mdash;go to infinity&mdash;for statistics to apply).
 
The ratio is a probability  written as
The quantity ''Q'' is known as the ''[[Partition function (statistical physics) |partition function]]''  of the subsystem. It is a sum over all energies that the subsystem can have. In the older literature ''Q'' is called ''Zustandssumme'', which is German for "sum over states", and is often denoted by ''Z''.  When we consider again as an example a vessel  with ''N'' interacting molecules at certain pressure and temperature, the sum is over the possible total  energies of all ''N'' molecules in the vessel.  
:<math>
\frac{N_j}{N} \equiv \mathcal{P}(\epsilon_j) = \frac{e^{-\epsilon_j/(kT)}}{Q}.
</math>
The quantity ''Q'' is known as the ''[[Partition function (statistical physics) |partition function]]''  of the system. It is a sum over all energies that the system can have. In the older literature ''Q'' is called ''Zustandssumme'', which is German for "sum over states", and is often denoted by ''Z''.  When we consider again the example of a vessel  with interacting molecules at certain pressure and temperature, the sum in the partition function is over the possible total  energies &epsilon;<sub>i</sub> of the  molecules in the vessel.  


In classical statistical physics, where energies are not discrete, the partition function of a system of ''N'' molecules is an integral over the 6<sup>''N''</sup>-dimensional [[phase space]] (space of momenta and positions). In the framework of the "old quantum theory"  it was was around 1913 discovered that the classical partition function of ''N'' molecules  must multiplied by a quantum factor. The classical partition function is,
In classical statistical physics, where energies are not discrete, the partition function of a system of ''n'' molecules is not a sum over the possible energies of the system, but an integral over the 6<sup>''n''</sup>-dimensional [[phase space]] (space of momenta and positions). In the framework of the "old quantum theory"  it was discovered in 1912  that the classical partition function of ''n'' molecules  must multiplied by a quantum factor. The classical partition function is,
:<math>
:<math>
Q_\mathrm{class} = \frac{1}{N! h^{3N}} \int E^{-E(p,q)/(kT)}  
Q_\mathrm{class} = \frac{1}{n! h^{3n}} \int e^{-\epsilon(p,q)/(kT)}  
\mathrm{d}\mathbf{q}_1 \cdots \mathrm{d}\mathbf{q}_N \,\mathrm{d}\mathbf{p}_1 \cdots \mathrm{d}\mathbf{p}_N,
\mathrm{d}\mathbf{q}_1 \cdots \mathrm{d}\mathbf{q}_n \,\mathrm{d}\mathbf{p}_1 \cdots \mathrm{d}\mathbf{p}_n,
</math>
</math>
where ''h'' is [[Planck's constant]] and ''N''! = 1 &times; 2&times; ... &times; ''N'' (the [[factorial]] of ''N'').
where ''h'' is [[Planck's constant]] and ''n''! = 1 &times; 2&times; ... &times; ''n'' (the [[factorial]] of ''n'').
 
As a final remark: in quantum statistical thermodynamics the Boltzmann distribution appears as the high-temperature limit of both [[Bose-Einstein statistics]] (valid for [[boson]]s) and [[Fermi-Dirac statistics]] (valid for [[fermions]]).
 
==Note==
<references />

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In classical statistical physics, the Boltzmann distribution expresses the relative probability that a subsystem of a physical system has a certain energy. The subsystem must part of a physical system that is in thermal equilibrium, that is, the system must have a well-defined (absolute) temperature. For instance, a subsystem can be a single molecule in, say, one mole of an ideal gas. Then the Boltzmann distribution applies to the energies of the individual gas molecules, provided the ideal gas is in thermal equilibrium.

The Boltzmann distribution (also known as the Maxwell-Boltzmann distribution) was proposed in 1859 by the Scotsman James Clerk Maxwell for the statistical distribution of the kinetic energies of ideal gas molecules. Consider an ideal gas of absolute temperature T. Let n1 be the number of molecules with kinetic energy E1 and n2 be the number with kinetic energy E2, then according to the Maxwell-Boltzmann distribution law the relative probability is the ratio,

where k is the Boltzmann constant. Most noticeable in this expression are (i) the energy in an exponential, (ii) the inverse temperature in the exponent, and (iii) the appearance of the natural constant k. Note that an argument of an exponential must be dimensionless and that accordingly kT has the dimension energy.

As discovered in 1871 by the Austrian Ludwig Boltzmann, the molecular energies in equation (1) may, in addition to the translational energy considered by Maxwell, contain rotational and vibrational energies of the molecules. Also interactions with an external field may be included. If a system, as for instance a column of air of constant temperature (zero lapse rate), is in the gravitational field of the Earth, each molecular energy contains the additional term mgh, where m is the molecular mass, g the gravitational acceleration and h the height of the molecule above the surface of the Earth. Thus, the ratio of the number of molecules at height h1 and h2 is,

where we made the assumption that the difference in molecular kinetic energies at the two heights is small in comparison to the difference in potential energies:

E2E1 << mg(h2h1),

so that the difference in kinetic energies may be omitted.

Generalization

A few years after Boltzmann, the American Josiah Willard Gibbs gave a further formalization and generalization (ca. 1877). Gibbs introduced what he called an ensemble, a "supersystem" consisting of a statistically large number of identical systems. For instance, the systems may be identical vessels containing the same number of the same real gas molecules at the same temperature and pressure. Further Gibbs assumed that the ensemble, just like a system of gas molecules, is in thermal equilibrium, i.e., the systems are in thermal contact so that they can exchange heat. In the example that the systems are gas-filled vessels, this is achieved by requiring that the vessels are in mutual contact through heat-conducting walls.

Gibbs assumed[1] that the Maxwell-Boltzmann law, equation (1), holds for the energies of the systems in the ensemble. This generalization, applied to the example of an ensemble consisting of gas-filled vessels, means that the energy of a gas molecule in equation (1) is replaced by the total energy of the molecules in a vessel; a "one-molecule" energy is promoted to a "one-vessel" energy. Because of molecular interactions (that are absent in an ideal gas), a one-vessel energy cannot be written as a sum of one-molecule energies. This is the main reason for Gibbs' generalization from a single vessel of gas to an ensemble of vessels, or, in more general terms, the generalization from an ideal gas to an ensemble of (rather arbitrary) systems. Just as the molecules in an ideal gas, the systems in the ensemble do not interact other than by exchanging heat.

The absolute probability for a system to have total energy εj can be obtained from equation (1) by normalizing. Let us assume, for convenience sake, that the one-system energies are discrete (as they often are in quantum mechanics) running from ε0 to ε , then

which gives

where Nj is the number of systems that have energy εj and N is the total number of systems in the ensemble (N must be very large—go to infinity—for statistics to apply). The ratio is a probability written as

The quantity Q is known as the partition function of the system. It is a sum over all energies that the system can have. In the older literature Q is called Zustandssumme, which is German for "sum over states", and is often denoted by Z. When we consider again the example of a vessel with interacting molecules at certain pressure and temperature, the sum in the partition function is over the possible total energies εi of the molecules in the vessel.

In classical statistical physics, where energies are not discrete, the partition function of a system of n molecules is not a sum over the possible energies of the system, but an integral over the 6n-dimensional phase space (space of momenta and positions). In the framework of the "old quantum theory" it was discovered in 1912 that the classical partition function of n molecules must multiplied by a quantum factor. The classical partition function is,

where h is Planck's constant and n! = 1 × 2× ... × n (the factorial of n).

As a final remark: in quantum statistical thermodynamics the Boltzmann distribution appears as the high-temperature limit of both Bose-Einstein statistics (valid for bosons) and Fermi-Dirac statistics (valid for fermions).

Note

  1. To get the history correct: Gibbs made a few very fundamental assumptions from which he derived the equivalence of equation (1).