Virial theorem: Difference between revisions
imported>Paul Wormer (New page: {{subpages}} In mechanics, a '''virial''' of a stable system of ''n'' particles is a quantity proposed by Rudolf Clausius in 1870. The virial is defined by :<math> \tfrac{1}{2} \s...) |
imported>Paul Wormer |
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==Application== | ==Application== | ||
An interesting application arises when | An interesting application arises when the potential ''V'' is of the form | ||
:<math> | :<math> | ||
V = | V = \sum_{i=1}^n V(\mathbf{r}_i)\quad \hbox{with}\quad V(\mathbf{r}_i) = a_i r_i ^k\quad\hbox{and}\quad r_i = (x_i^2+y_i^2+z_i^2)^{1/2}, | ||
</math> | </math> | ||
where '' | where ''a''<sub>''i''</sub> is some constant (independent of space and time). | ||
An example of such potential is given by [[Hooke's law]] with ''k'' = 2 and [[Coulomb's law]] with ''k'' = −1. | An example of such potential is given by [[Hooke's law]] with ''k'' = 2 and [[Coulomb's law]] with ''k'' = −1. | ||
The force derived from a potential is | The force derived from a potential is | ||
:<math> | :<math> | ||
\mathbf{F} = -\boldsymbol{\nabla}V \equiv -\left( \frac{ \partial V}{\partial | \mathbf{F}_i = -\boldsymbol{\nabla}_i V \equiv -\left( \frac{ \partial V}{\partial x_i},\; \frac{ \partial V}{\partial y_i},\; \frac{ \partial V}{\partial z_i}\right) | ||
</math> | </math> | ||
Consider | Consider | ||
:<math> | :<math> | ||
\frac{ \partial V}{\partial | \frac{ \partial V}{\partial x_i} = a_i \frac{ \partial (r_i)^k}{\partial x_i} = a_i k (r_i)^{k-1} \frac{ \partial r_i}{\partial x_i}= a_i k (r_i)^{k-1} \frac{x_i}{r_i} = k \frac{x_i}{r_i^2} V(\mathbf{r}_i). | ||
</math> | |||
Hence | |||
:<math> | |||
\mathbf{F}_i = - k V(\mathbf{r}_i) \frac{\mathbf{r}_i}{r_i^2}. | |||
</math> | </math> | ||
Then applying this for ''i'' = 1, … ''n'', | Then applying this for ''i'' = 1, … ''n'', | ||
:<math> | :<math> | ||
2\langle T \rangle = k \sum_{i=1}^n \left \langle V(\mathbf{r}_i) \cdot \frac{\mathbf{r}_i\cdot \mathbf{r}_i}{r_i^2}\right\rangle = | 2\langle T \rangle = k \sum_{i=1}^n \left \langle V(\mathbf{r}_i) \cdot \frac{\mathbf{r}_i\cdot \mathbf{r}_i}{r_i^2}\right\rangle = | ||
k\langle V\rangle \quad\hbox{ | k\langle V\rangle \quad\hbox{where}\quad V = \sum_{i=1}^n V(\mathbf{r}_i). | ||
</math> | </math> | ||
For instance, for a system of charged particles interacting through a Coulomb interaction: | For instance, for a system of charged particles interacting through a Coulomb interaction: | ||
Line 62: | Line 65: | ||
2\langle T \rangle = - \langle V \rangle. | 2\langle T \rangle = - \langle V \rangle. | ||
</math> | </math> | ||
==Quantum mechanics== | ==Quantum mechanics== | ||
The virial theorem holds also in quantum mechanics. Quantum mechanically the angular brackets do not indicate a time-average, but an expectation value with respect to an exact stationary eigenstate of the Hamiltonian of the system. The theorem will be proved and applied to the special case of a potential that has a ''r''<sup>''k''</sup>-like dependence. Everywhere Planck's constant ℏ is taken to be one. | The virial theorem holds also in quantum mechanics. Quantum mechanically the angular brackets do not indicate a time-average, but an expectation value with respect to an exact stationary eigenstate of the Hamiltonian of the system. The theorem will be proved and applied to the special case of a potential that has a ''r''<sup>''k''</sup>-like dependence. Everywhere Planck's constant ℏ is taken to be one. |
Revision as of 08:43, 15 February 2010
In mechanics, a virial of a stable system of n particles is a quantity proposed by Rudolf Clausius in 1870. The virial is defined by
where Fi is the total force acting on the i th particle and ri is the position of the i th particle; the dot stands for an inner product between the two 3-vectors. Indicate long-time averages by angular brackets. The importance of the virial arises from the virial theorem, which connects the long-time average of the virial to the long-time average ⟨ T ⟩ of the total kinetic energy T of the n-particle system,
Proof of the virial theorem
Consider the quantity G defined by
The vector pi is the momentum of particle i. Differentiate G with respect to time:
Use Newtons's second law and the definition of kinetic energy:
and it follows that
Averaging over time gives:
If the system is stable, G(t) at time t = 0 and at time t = T is finite. Hence, if T goes to infinity, the quantity on the right hand side goes to zero. Alternatively, if the system is periodic with period T, G(T) = G(0) and the right hand side will also vanish. Whatever the cause, we assume that the time average of the time derivative of G is zero, and hence
which proves the virial theorem.
Application
An interesting application arises when the potential V is of the form
where ai is some constant (independent of space and time).
An example of such potential is given by Hooke's law with k = 2 and Coulomb's law with k = −1. The force derived from a potential is
Consider
Hence
Then applying this for i = 1, … n,
For instance, for a system of charged particles interacting through a Coulomb interaction:
Quantum mechanics
The virial theorem holds also in quantum mechanics. Quantum mechanically the angular brackets do not indicate a time-average, but an expectation value with respect to an exact stationary eigenstate of the Hamiltonian of the system. The theorem will be proved and applied to the special case of a potential that has a rk-like dependence. Everywhere Planck's constant ℏ is taken to be one.
Let us consider a n-particle Hamiltonian of the form
where mj is the mass of the j-th particle. The momentum operator is
Using the self-adjointness of H and the definition of a commutator one has for an arbitrary operator G,
In order to obtain the virial theorem, we consider
Use
Define
Use
and we find
The quantum mechanical virial theorem follows
where ⟨ … ⟩ stands for an expectation value with respect to the exact eigenfunction Ψ of H.
If V is of the form
it follows that
From this:
- Failed to parse (SVG (MathML can be enabled via browser plugin): Invalid response ("Math extension cannot connect to Restbase.") from server "https://wikimedia.org/api/rest_v1/":): {\displaystyle 2\langle T\rangle = k \sum_{j=1}^n a_j \langle (\mathbf{r}_j\cdot\mathbf{r}_j)\, (r_j)^{k-2}\rangle = k \langle V \rangle }
For instance, for a stable atom (consisting of charged particles with Coulomb interaction): k = −1, and hence 2⟨T ⟩ = −⟨V ⟩.