Virial theorem

Template:Short description

In mechanics, the virial theorem provides a general equation that relates the average over time of the total kinetic energy of a stable system of discrete particles, bound by a conservative force (where the work done is independent of path), with that of the total potential energy of the system. Mathematically, the theorem states that $${\displaystyle ⟨T⟩=-\frac{1}{2}{\displaystyle \sum _{k=1}^N}⟨{𝐅}_k\cdot {𝐫}_k⟩,}$$ where Template:Mvar is the total kinetic energy of the Template:Mvar particles, Template:Math represents the force on the Template:Mvarth particle, which is located at position Template:Math, and angle brackets represent the average over time of the enclosed quantity. The word virial for the right-hand side of the equation derives from Template:Lang, the Latin word for "force" or "energy", and was given its technical definition by Rudolf Clausius in 1870.^[1]

The significance of the virial theorem is that it allows the average total kinetic energy to be calculated even for very complicated systems that defy an exact solution, such as those considered in statistical mechanics; this average total kinetic energy is related to the temperature of the system by the equipartition theorem. However, the virial theorem does not depend on the notion of temperature and holds even for systems that are not in thermal equilibrium. The virial theorem has been generalized in various ways, most notably to a tensor form.

If the force between any two particles of the system results from a potential energy Template:Math that is proportional to some power Template:Mvar of the interparticle distance Template:Mvar, the virial theorem takes the simple form $${\displaystyle 2⟨T⟩=n⟨V_{\text{TOT}}⟩.}$$

Thus, twice the average total kinetic energy Template:Math equals Template:Mvar times the average total potential energy Template:Math. Whereas Template:Math represents the potential energy between two particles of distance Template:Mvar, Template:Math represents the total potential energy of the system, i.e., the sum of the potential energy Template:Math over all pairs of particles in the system. A common example of such a system is a star held together by its own gravity, where Template:Nobr

In 1870, Rudolf Clausius delivered the lecture "On a Mechanical Theorem Applicable to Heat" to the Association for Natural and Medical Sciences of the Lower Rhine, following a 20-year study of thermodynamics. The lecture stated that the mean vis viva of the system is equal to its virial, or that the average kinetic energy is one half of the average potential energy. The virial theorem can be obtained directly from Lagrange's identityTemplate:Moved resource as applied in classical gravitational dynamics, the original form of which was included in Lagrange's "Essay on the Problem of Three Bodies" published in 1772. Carl Jacobi's generalization of the identity to N bodies and to the present form of Laplace's identity closely resembles the classical virial theorem. However, the interpretations leading to the development of the equations were very different, since at the time of development, statistical dynamics had not yet unified the separate studies of thermodynamics and classical dynamics.^[2] The theorem was later utilized, popularized, generalized and further developed by James Clerk Maxwell, Lord Rayleigh, Henri Poincaré, Subrahmanyan Chandrasekhar, Enrico Fermi, Paul Ledoux, Richard Bader and Eugene Parker. Fritz Zwicky was the first to use the virial theorem to deduce the existence of unseen matter, which is now called dark matter. Richard Bader showed that the charge distribution of a total system can be partitioned into its kinetic and potential energies that obey the virial theorem.^[3] As another example of its many applications, the virial theorem has been used to derive the Chandrasekhar limit for the stability of white dwarf stars.

Consider Template:Math particles with equal mass Template:Mvar, acted upon by mutually attractive forces. Suppose the particles are at diametrically opposite points of a circular orbit with radius Template:Mvar. The velocities are Template:Math and Template:Math, which are normal to forces Template:Math and Template:Math. The respective magnitudes are fixed at Template:Mvar and Template:Mvar. The average kinetic energy of the system in an interval of time from Template:Math to Template:Math is $${\displaystyle ⟨T⟩=\frac{1}{t_2-t_1}{\displaystyle \underset{t_1}{\overset{t_2}{\int }}}{\displaystyle \sum _{k=1}^N}\frac{1}{2}{m}_k|{𝐯}_k(t){|}^{2}dt=\frac{1}{t_2-t_1}{\displaystyle \underset{t_1}{\overset{t_2}{\int }}}(\frac{1}{2}m|{𝐯}_1(t){|}^2+\frac{1}{2}m|{𝐯}_2(t){|}^2)dt=m{v}^2.}$$ Taking center of mass as the origin, the particles have positions Template:Math and Template:Math with fixed magnitude Template:Mvar. The attractive forces act in opposite directions as positions, so Template:Math. Applying the centripetal force formula Template:Math results in $${\displaystyle -\frac{1}{2}{\displaystyle \sum _{k=1}^N}⟨{𝐅}_k\cdot {𝐫}_k⟩=-\frac{1}{2}(-Fr-Fr)=Fr=\frac{m{v}^2}{r}\cdot r=m{v}^2=⟨T⟩,}$$ as required. Note: If the origin is displaced, then we'd obtain the same result. This is because the dot product of the displacement with equal and opposite forces Template:Math, Template:Math results in net cancellation.

Although the virial theorem depends on averaging the total kinetic and potential energies, the presentation here postpones the averaging to the last step.

For a collection of Template:Mvar point particles, the scalar moment of inertia Template:Mvar about the origin is $${\displaystyle I={\displaystyle \sum _{k=1}^N}{m}_k|{𝐫}_k{|}^2={\displaystyle \sum _{k=1}^N}{m}_k{r}_k^2,}$$ where Template:Math and Template:Math represent the mass and position of the Template:Mvarth particle. Template:Math is the position vector magnitude. Consider the scalar $${\displaystyle G={\displaystyle \sum _{k=1}^N}{𝐩}_k\cdot {𝐫}_k,}$$ where Template:Math is the momentum vector of the Template:Mvarth particle.^[4] Assuming that the masses are constant, Template:Mvar is one-half the time derivative of this moment of inertia: $${\displaystyle \begin{array}{cc}\frac{1}{2}\frac{dI}{dt}& =\frac{1}{2}\frac{d}{dt}{\displaystyle \sum _{k=1}^N}{m}_k{𝐫}_k\cdot {𝐫}_k\\ & ={\displaystyle \sum _{k=1}^N}{m}_k\frac{d{𝐫}_k}{dt}\cdot {𝐫}_k\\ & ={\displaystyle \sum _{k=1}^N}{𝐩}_k\cdot {𝐫}_k=G.\end{array}}$$ In turn, the time derivative of Template:Mvar is $${\displaystyle \begin{array}{cc}\frac{dG}{dt}& ={\displaystyle \sum _{k=1}^N}{𝐩}_k\cdot \frac{d{𝐫}_k}{dt}+{\displaystyle \sum _{k=1}^N}\frac{d{𝐩}_k}{dt}\cdot {𝐫}_k\\ & ={\displaystyle \sum _{k=1}^N}{m}_k\frac{d{𝐫}_k}{dt}\cdot \frac{d{𝐫}_k}{dt}+{\displaystyle \sum _{k=1}^N}{𝐅}_k\cdot {𝐫}_k\\ & =2T+{\displaystyle \sum _{k=1}^N}{𝐅}_k\cdot {𝐫}_k,\end{array}}$$ where Template:Math is the mass of the Template:Mvarth particle, Template:Math is the net force on that particle, and Template:Mvar is the total kinetic energy of the system according to the Template:Math velocity of each particle, $${\displaystyle T=\frac{1}{2}{\displaystyle \sum _{k=1}^N}{m}_k{v}_k^2=\frac{1}{2}{\displaystyle \sum _{k=1}^N}{m}_k\frac{d{𝐫}_k}{dt}\cdot \frac{d{𝐫}_k}{dt}.}$$

The total force Template:Math on particle Template:Mvar is the sum of all the forces from the other particles Template:Mvar in the system: $${\displaystyle {𝐅}_k={\displaystyle \sum _{j=1}^N}{𝐅}_{jk},}$$ where Template:Math is the force applied by particle Template:Mvar on particle Template:Mvar. Hence, the virial can be written as $${\displaystyle -\frac{1}{2}{\displaystyle \sum _{k=1}^N}{𝐅}_k\cdot {𝐫}_k=-\frac{1}{2}{\displaystyle \sum _{k=1}^N}{\displaystyle \sum _{j=1}^N}{𝐅}_{jk}\cdot {𝐫}_k.}$$

Since no particle acts on itself (i.e., Template:Math for Template:Math), we split the sum in terms below and above this diagonal and add them together in pairs: $${\displaystyle \begin{array}{cc}{\displaystyle \sum _{k=1}^N}{𝐅}_k\cdot {𝐫}_k& ={\displaystyle \sum _{k=1}^N}{\displaystyle \sum _{j=1}^N}{𝐅}_{jk}\cdot {𝐫}_k={\displaystyle \sum _{k=2}^N}{\displaystyle \sum _{j=1}^{k-1}}{𝐅}_{jk}\cdot {𝐫}_k+{\displaystyle \sum _{k=1}^{N-1}}{\displaystyle \sum _{j=k+1}^N}{𝐅}_{jk}\cdot {𝐫}_k\\ & ={\displaystyle \sum _{k=2}^N}{\displaystyle \sum _{j=1}^{k-1}}{𝐅}_{jk}\cdot {𝐫}_k+{\displaystyle \sum _{j=2}^N}{\displaystyle \sum _{k=1}^{j-1}}{𝐅}_{jk}\cdot {𝐫}_k={\displaystyle \sum _{k=2}^N}{\displaystyle \sum _{j=1}^{k-1}}({𝐅}_{jk}\cdot {𝐫}_k+{𝐅}_{kj}\cdot {𝐫}_j)\\ & ={\displaystyle \sum _{k=2}^N}{\displaystyle \sum _{j=1}^{k-1}}({𝐅}_{jk}\cdot {𝐫}_k-{𝐅}_{jk}\cdot {𝐫}_j)={\displaystyle \sum _{k=2}^N}{\displaystyle \sum _{j=1}^{k-1}}{𝐅}_{jk}\cdot ({𝐫}_k-{𝐫}_j),\end{array}}$$ where we have used Newton's third law of motion, i.e., Template:Math (equal and opposite reaction).

It often happens that the forces can be derived from a potential energy Template:Mvar that is a function only of the distance Template:Math between the point particles Template:Mvar and Template:Mvar. Since the force is the negative gradient of the potential energy, we have in this case $${\displaystyle {𝐅}_{jk}=-{\mathrm{\nabla }}_{{𝐫}_k}{V}_{jk}=-\frac{d{V}_{jk}}{d{r}_{jk}}\left(\frac{{𝐫}_k-{𝐫}_j}{r_{jk}}\right),}$$ which is equal and opposite to Template:Math, the force applied by particle Template:Mvar on particle Template:Mvar, as may be confirmed by explicit calculation. Hence, $${\displaystyle \begin{array}{cc}{\displaystyle \sum _{k=1}^N}{𝐅}_k\cdot {𝐫}_k& ={\displaystyle \sum _{k=2}^N}{\displaystyle \sum _{j=1}^{k-1}}{𝐅}_{jk}\cdot ({𝐫}_k-{𝐫}_j)\\ & =-{\displaystyle \sum _{k=2}^N}{\displaystyle \sum _{j=1}^{k-1}}\frac{d{V}_{jk}}{d{r}_{jk}}\frac{|{𝐫}_k-{𝐫}_j{|}^2}{r_{jk}}\\ & =-{\displaystyle \sum _{k=2}^N}{\displaystyle \sum _{j=1}^{k-1}}\frac{d{V}_{jk}}{d{r}_{jk}}{r}_{jk}.\end{array}}$$

Thus $${\displaystyle \frac{dG}{dt}=2T+{\displaystyle \sum _{k=1}^N}{𝐅}_k\cdot {𝐫}_k=2T-{\displaystyle \sum _{k=2}^N}{\displaystyle \sum _{j=1}^{k-1}}\frac{d{V}_{jk}}{d{r}_{jk}}{r}_{jk}.}$$

In a common special case, the potential energy Template:Mvar between two particles is proportional to a power Template:Mvar of their distance Template:Mvar: $${\displaystyle V_{jk}=\alpha r_{jk}^n,}$$ where the coefficient Template:Mvar and the exponent Template:Mvar are constants. In such cases, the virial is $${\displaystyle \begin{array}{cc}-\frac{1}{2}{\displaystyle \sum _{k=1}^N}{𝐅}_k\cdot {𝐫}_k& =\frac{1}{2}{\displaystyle \sum _{k=1}^N}\sum _{j<k}\frac{d{V}_{jk}}{d{r}_{jk}}{r}_{jk}\\ & =\frac{1}{2}{\displaystyle \sum _{k=1}^N}\sum _{j<k}n\alpha r_{jk}^{n-1}{r}_{jk}\\ & =\frac{1}{2}{\displaystyle \sum _{k=1}^N}\sum _{j<k}n{V}_{jk}=\frac{n}{2}{V}_{\text{TOT}},\end{array}}$$ where $${\displaystyle V_{\text{TOT}}={\displaystyle \sum _{k=1}^N}\sum _{j<k}{V}_{jk}}$$ is the total potential energy of the system.

Thus $${\displaystyle \frac{dG}{dt}=2T+{\displaystyle \sum _{k=1}^N}{𝐅}_k\cdot {𝐫}_k=2T-n{V}_{\text{TOT}}.}$$

For gravitating systems the exponent Template:Mvar equals −1, giving Lagrange's identity $${\displaystyle \frac{dG}{dt}=\frac{1}{2}\frac{d^{2}I}{d{t}^2}=2T+V_{\text{TOT}},}$$ which was derived by Joseph-Louis Lagrange and extended by Carl Jacobi.

The average of this derivative over a duration Template:Mvar is defined as $${\displaystyle {⟨\frac{dG}{dt}⟩}_{\tau }=\frac{1}{\tau }{\displaystyle \underset{0}{\overset{\tau }{\int }}}\frac{dG}{dt}dt=\frac{1}{\tau }{\displaystyle \underset{G(0)}{\overset{G(\tau )}{\int }}}dG=\frac{G(\tau )-G(0)}{\tau },}$$ from which we obtain the exact equation $${\displaystyle {⟨\frac{dG}{dt}⟩}_{\tau }=2⟨T{⟩}_{\tau }+{\displaystyle \sum _{k=1}^N}⟨{𝐅}_k\cdot {𝐫}_k{⟩}_{\tau }.}$$

The virial theorem states that if Template:Math, then $${\displaystyle 2⟨T{⟩}_{\tau }=-{\displaystyle \sum _{k=1}^N}⟨{𝐅}_k\cdot {𝐫}_k{⟩}_{\tau }.}$$

There are many reasons why the average of the time derivative might vanish. One often-cited reason applies to stably bound systems, that is, to systems that hang together forever and whose parameters are finite. In this case, velocities and coordinates of the particles of the system have upper and lower limits, so that Template:Math is bounded between two extremes, Template:Math and Template:Math, and the average goes to zero in the limit of infinite Template:Mvar: $${\displaystyle \underset{\tau \to \mathrm{\infty }}{\lim }\left|{⟨\frac{d{G}^{\text{bound}}}{dt}⟩}_{\tau }\right|=\underset{\tau \to \mathrm{\infty }}{\lim }\left|\frac{G(\tau )-G(0)}{\tau }\right|\le \underset{\tau \to \mathrm{\infty }}{\lim }\frac{G_{\max }-G_{\min }}{\tau }=0.}$$

Even if the average of the time derivative of Template:Mvar is only approximately zero, the virial theorem holds to the same degree of approximation.

For power-law forces with an exponent Template:Mvar, the general equation holds: $${\displaystyle ⟨T{⟩}_{\tau }=-\frac{1}{2}{\displaystyle \sum _{k=1}^N}⟨{𝐅}_k\cdot {𝐫}_k{⟩}_{\tau }=\frac{n}{2}⟨V_{\text{TOT}}{⟩}_{\tau }.}$$

For gravitational attraction, Template:Math, and the average kinetic energy equals half of the average negative potential energy: $${\displaystyle ⟨T{⟩}_{\tau }=-\frac{1}{2}⟨V_{\text{TOT}}{⟩}_{\tau }.}$$

This general result is useful for complex gravitating systems such as planetary systems or galaxies.

A simple application of the virial theorem concerns galaxy clusters. If a region of space is unusually full of galaxies, it is safe to assume that they have been together for a long time, and the virial theorem can be applied. Doppler effect measurements give lower bounds for their relative velocities, and the virial theorem gives a lower bound for the total mass of the cluster, including any dark matter.

If the ergodic hypothesis holds for the system under consideration, the averaging need not be taken over time; an ensemble average can also be taken, with equivalent results.

Although originally derived for classical mechanics, the virial theorem also holds for quantum mechanics, as first shown by Vladimir Fock^[5] using the Ehrenfest theorem.

Evaluate the commutator of the Hamiltonian $${\displaystyle H=V(\{X_i\})+\sum _n\frac{P_n^2}{2m_n}}$$ with the position operator Template:Mvar and the momentum operator $${\displaystyle P_n=-i\hslash \frac{d}{d{X}_n}}$$ of particle Template:Mvar, $${\displaystyle [H,X_n{P}_n]=X_n[H,P_n]+[H,X_n]P_n=i\hslash X_n\frac{dV}{d{X}_n}-i\hslash \frac{P_n^2}{m_n}.}$$

Summing over all particles, one finds that for $${\displaystyle Q=\sum _n{X}_n{P}_n}$$ the commutator is $${\displaystyle \frac{i}{\hslash }[H,Q]=2T-\sum _n{X}_n\frac{dV}{d{X}_n},}$$ where $T=\sum _n{P}_n^2/2m_n$ is the kinetic energy. The left-hand side of this equation is just Template:Math, according to the Heisenberg equation of motion. The expectation value Template:Math of this time derivative vanishes in a stationary state, leading to the quantum virial theorem: $${\displaystyle 2⟨T⟩=\sum _n⟨X_n\frac{dV}{d{X}_n}⟩.}$$

Template:Unreferenced section In the field of quantum mechanics, there exists another form of the virial theorem, applicable to localized solutions to the stationary nonlinear Schrödinger equation or Klein–Gordon equation, is Pokhozhaev's identity,^[6] also known as Derrick's theorem. Let ${\displaystyle g(s)}$ be continuous and real-valued, with ${\displaystyle g(0)=0}$.

Denote $G(s)={\int }_0^{s}g(t)dt$. Let $${\displaystyle u\in L_{\text{loc}}^{\mathrm{\infty }}({ℝ}^n),\mathrm{\nabla }u\in L^2({ℝ}^n),G(u(\cdot ))\in L^1({ℝ}^n),n\in \mathbb{N}}$$ be a solution to the equation $${\displaystyle -{\mathrm{\nabla }}^{2}u=g(u),}$$ in the sense of distributions. Then ${\displaystyle u}$ satisfies the relation $${\displaystyle \left(\frac{n-2}{2}\right)\underset{{ℝ}^n}{\int }|\mathrm{\nabla }u(x){|}^{2}dx=n\underset{{ℝ}^n}{\int }G(u(x))dx.}$$

Template:Unreferenced sectionFor a single particle in special relativity, it is not the case that Template:Math. Instead, it is true that Template:Math, where Template:Mvar is the Lorentz factor $${\displaystyle \gamma =\frac{1}{\sqrt{1-\frac{v^2}{c^2}}},}$$ and Template:Math. We have $${\displaystyle \begin{array}{cc}\frac{1}{2}𝐩\cdot 𝐯& =\frac{1}{2}\mathit{\beta }\gamma mc\cdot \mathit{\beta }c\\ & =\frac{1}{2}\gamma {\beta }^{2}m{c}^2\\ & =\left(\frac{\gamma {\beta }^2}{2(\gamma -1)}\right)T.\end{array}}$$ The last expression can be simplified to $${\displaystyle \left(\frac{1+\sqrt{1-{\beta }^2}}{2}\right)T=\left(\frac{\gamma +1}{2\gamma }\right)T.}$$ Thus, under the conditions described in earlier sections (including Newton's third law of motion, Template:Math, despite relativity), the time average for Template:Mvar particles with a power law potential is $${\displaystyle \frac{n}{2}{⟨V_{\text{TOT}}⟩}_{\tau }={⟨{\displaystyle \sum _{k=1}^N}\left(\frac{1+\sqrt{1-{\beta }_k^2}}{2}\right)T_k⟩}_{\tau }={⟨{\displaystyle \sum _{k=1}^N}\left(\frac{{\gamma }_k+1}{2{\gamma }_k}\right)T_k⟩}_{\tau }.}$$ In particular, the ratio of kinetic energy to potential energy is no longer fixed, but necessarily falls into an interval: $${\displaystyle \frac{2⟨T_{\text{TOT}}⟩}{n⟨V_{\text{TOT}}⟩}\in [1,2],}$$ where the more relativistic systems exhibit the larger ratios.

The virial theorem has a particularly simple form for periodic motion. It can be used to perform perturbative calculation for nonlinear oscillators.^[7]

It can also be used to study motion in a central potential.^[4] If the central potential is of the form ${\displaystyle U\propto r^n}$, the virial theorem simplifies to ${\displaystyle ⟨T⟩=\frac{n}{2}⟨U⟩}$.Template:Citation needed In particular, for gravitational or electrostatic (Coulomb) attraction, ${\displaystyle ⟨T⟩=-\frac{1}{2}⟨U⟩}$.

Analysis based on Sivardiere, 1986.^[7] For a one-dimensional oscillator with mass ${\displaystyle m}$, position ${\displaystyle x}$, driving force ${\displaystyle F\cos (\omega t)}$, spring constant ${\displaystyle k}$, and damping coefficient ${\displaystyle \gamma }$, the equation of motion is $${\displaystyle m\underset{\text{acceleration}}{\underbrace{\frac{d^{2}x}{d{t}^2}}}=\underset{\text{spring}}{\underbrace{-kx\phantom{\frac{d}{d}}}}\underset{\text{friction}}{\underbrace{-\gamma \frac{dx}{dt}}}\underset{\text{external driving}}{\underbrace{+F\cos (\omega t)\phantom{\frac{d}{d}}}}.}$$

When the oscillator has reached a steady state, it performs a stable oscillation ${\displaystyle x=X\cos (\omega t+\phi )}$, where ${\displaystyle X}$ is the amplitude, and ${\displaystyle \phi }$ is the phase angle.

Applying the virial theorem, we have ${\displaystyle m⟨\dot{x}\dot{x}⟩=k⟨xx⟩+\gamma ⟨x\dot{x}⟩-F⟨\cos (\omega t)x⟩}$, which simplifies to ${\displaystyle F\cos (\phi )=m({\omega }_0^2-{\omega }^2)X}$, where ${\displaystyle {\omega }_0=\sqrt{k/m}}$ is the natural frequency of the oscillator.

To solve the two unknowns, we need another equation. In steady state, the power lost per cycle is equal to the power gained per cycle: $${\displaystyle \underset{\text{power dissipated}}{\underbrace{⟨\dot{x}\gamma \dot{x}⟩}}=\underset{\text{power input}}{\underbrace{⟨\dot{x}F\cos \omega t⟩}},}$$ which simplifies to ${\displaystyle \sin \phi =-\frac{\gamma X\omega }{F}}$.

Now we have two equations that yield the solution $${\displaystyle \{\begin{array}{c}X=\sqrt{{\displaystyle \frac{F^2}{{\gamma }^2{\omega }^2+m^2({\omega }_0^2-{\omega }^2{)}^2}}},\\ \tan \phi =-{\displaystyle \frac{\gamma \omega }{m({\omega }_0^2-{\omega }^2)}}.\end{array}}$$

Consider a container filled with an ideal gas consisting of point masses. The force applied to the point masses is the negative of the forces applied to the wall of the container, which is of the form ${\displaystyle d𝐅=-\widehat{𝐧}PdA}$, where ${\displaystyle \widehat{𝐧}}$ is the unit normal vector pointing outwards. Then the virial theorem states that $${\displaystyle ⟨T⟩=-\frac{1}{2}⟨\sum _i{𝐅}_i\cdot {𝐫}_i⟩=\frac{P}{2}\int \widehat{𝐧}\cdot 𝐫dA.}$$ By the divergence theorem, $\int \widehat{𝐧}\cdot 𝐫dA=\int \mathrm{\nabla }\cdot 𝐫dV=3\int dV=3V$. And since the average total kinetic energy $⟨T⟩=N⟨\frac{1}{2}m{v}^2⟩=N\cdot \frac{3}{2}kT$, we have ${\displaystyle PV=NkT}$.^[8]

In 1933, Fritz Zwicky applied the virial theorem to estimate the mass of Coma Cluster, and discovered a discrepancy of mass of about 450, which he explained as due to "dark matter".^[9] He refined the analysis in 1937, finding a discrepancy of about 500.^[10][11]

He approximated the Coma cluster as a spherical "gas" of ${\displaystyle N}$ stars of roughly equal mass ${\displaystyle m}$, which gives $⟨T⟩=\frac{1}{2}Nm⟨v^2⟩$. The total gravitational potential energy of the cluster is ${\displaystyle U=-\sum _{i<j}\frac{G{m}^2}{r_{i,j}}}$, giving $⟨U⟩=-G{m}^2\sum _{i<j}⟨1/r_{i,j}⟩$. Assuming the motion of the stars are all the same over a long enough time (ergodicity), $⟨U⟩=-\frac{1}{2}{N}^{2}G{m}^2⟨1/r⟩$.

Zwicky estimated ${\displaystyle ⟨U⟩}$ as the gravitational potential of a uniform ball of constant density, giving $⟨U⟩=-\frac{3}{5}\frac{G{N}^2{m}^2}{R}$.

So by the virial theorem, the total mass of the cluster is$${\displaystyle Nm=\frac{5⟨v^2⟩}{3G⟨\frac{1}{r}⟩}}$$

Zwicky${}_{1933}$^[9] estimated that there are ${\displaystyle N=800}$ galaxies in the cluster, each having observed stellar mass ${\displaystyle m=10^9{M}_{\odot }}$ (suggested by Hubble), and the cluster has radius ${\displaystyle R=10^6\text{ly}}$. He also measured the radial velocities of the galaxies by doppler shifts in galactic spectra to be ${\displaystyle ⟨v_r^2⟩=(1000\text{km/s}{)}^2}$. Assuming equipartition of kinetic energy, ${\displaystyle ⟨v^2⟩=3⟨v_r^2⟩}$.

By the virial theorem, the total mass of the cluster should be ${\displaystyle \frac{5R⟨v_r^2⟩}{G}\approx 3.6\times 10^{14}{M}_{\odot }}$. However, the observed mass is ${\displaystyle Nm=8\times 10^{11}{M}_{\odot }}$, meaning the total mass is 450 times that of observed mass.

Lord Rayleigh published a generalization of the virial theorem in 1900,^[12] which was partially reprinted in 1903.^[13] Henri Poincaré proved and applied a form of the virial theorem in 1911 to the problem of formation of the Solar System from a proto-stellar cloud (then known as cosmogony).^[14] A variational form of the virial theorem was developed in 1945 by Ledoux.^[15] A tensor form of the virial theorem was developed by Parker,^[16] Chandrasekhar^[17] and Fermi.^[18] The following generalization of the virial theorem has been established by Pollard in 1964 for the case of the inverse square law:^[19][20]Template:Failed verification $${\displaystyle 2\underset{\tau \to +\mathrm{\infty }}{\lim }⟨T{⟩}_{\tau }=\underset{\tau \to +\mathrm{\infty }}{\lim }⟨U{⟩}_{\tau }\text{if and only if}\underset{\tau \to +\mathrm{\infty }}{\lim }{\tau }^{-2}I(\tau )=0.}$$ A boundary term otherwise must be added.^[21]

The virial theorem can be extended to include electric and magnetic fields. The result is^[22]

$${\displaystyle \frac{1}{2}\frac{d^{2}I}{d{t}^2}+\underset{V}{\int }{x}_k\frac{\partial G_k}{\partial t}{d}^{3}r=2(T+U)+W^{\mathrm{E}}+W^{\mathrm{M}}-\int x_k(p_{ik}+T_{ik})d{S}_i,}$$

where Template:Mvar is the moment of inertia, Template:Mvar is the momentum density of the electromagnetic field, Template:Mvar is the kinetic energy of the "fluid", Template:Mvar is the random "thermal" energy of the particles, Template:Math and Template:Math are the electric and magnetic energy content of the volume considered. Finally, Template:Math is the fluid-pressure tensor expressed in the local moving coordinate system

$${\displaystyle p_{ik}=\mathrm{\Sigma }{n}^{\sigma }{m}^{\sigma }⟨v_i{v}_k{⟩}^{\sigma }-V_i{V}_k\mathrm{\Sigma }{m}^{\sigma }{n}^{\sigma },}$$

and Template:Math is the electromagnetic stress tensor,

$${\displaystyle T_{ik}=(\frac{{\epsilon }_0{E}^2}{2}+\frac{B^2}{2{\mu }_0}){\delta }_{ik}-({\epsilon }_0{E}_i{E}_k+\frac{B_i{B}_k}{{\mu }_0}).}$$

A plasmoid is a finite configuration of magnetic fields and plasma. With the virial theorem it is easy to see that any such configuration will expand if not contained by external forces. In a finite configuration without pressure-bearing walls or magnetic coils, the surface integral will vanish. Since all the other terms on the right hand side are positive, the acceleration of the moment of inertia will also be positive. It is also easy to estimate the expansion time Template:Mvar. If a total mass Template:Mvar is confined within a radius Template:Mvar, then the moment of inertia is roughly Template:Math, and the left hand side of the virial theorem is Template:Math. The terms on the right hand side add up to about Template:Math, where Template:Mvar is the larger of the plasma pressure or the magnetic pressure. Equating these two terms and solving for Template:Mvar, we find

$${\displaystyle \tau \sim \frac{R}{c_{\mathrm{s}}},}$$

where Template:Math is the speed of the ion acoustic wave (or the Alfvén wave, if the magnetic pressure is higher than the plasma pressure). Thus the lifetime of a plasmoid is expected to be on the order of the acoustic (or Alfvén) transit time.

In case when in the physical system the pressure field, the electromagnetic and gravitational fields are taken into account, as well as the field of particles’ acceleration, the virial theorem is written in the relativistic form as follows:^[23]

$${\displaystyle ⟨W_k⟩\approx -0.6{\displaystyle \sum _{k=1}^N}⟨{𝐅}_k\cdot {𝐫}_k⟩,}$$

where the value Template:Math exceeds the kinetic energy of the particles Template:Mvar by a factor equal to the Lorentz factor Template:Math of the particles at the center of the system. Under normal conditions we can assume that Template:Math, then we can see that in the virial theorem the kinetic energy is related to the potential energy not by the coefficient Template:Sfrac, but rather by the coefficient close to 0.6. The difference from the classical case arises due to considering the pressure field and the field of particles’ acceleration inside the system, while the derivative of the scalar Template:Mvar is not equal to zero and should be considered as the material derivative.

An analysis of the integral theorem of generalized virial makes it possible to find, on the basis of field theory, a formula for the root-mean-square speed of typical particles of a system without using the notion of temperature:^[24]

$${\displaystyle v_{\mathrm{r}\mathrm{m}\mathrm{s}}=c\sqrt{1-\frac{4\pi \eta {\rho }_0{r}^2}{c^2{\gamma }_c^2{\sin }^2\left(\frac{r}{c}\sqrt{4\pi \eta {\rho }_0}\right)}},}$$

where ${\displaystyle c}$ is the speed of light, ${\displaystyle \eta }$ is the acceleration field constant, ${\displaystyle {\rho }_0}$ is the mass density of particles, ${\displaystyle r}$ is the current radius.

Unlike the virial theorem for particles, for the electromagnetic field the virial theorem is written as follows:^[25] $${\displaystyle E_{kf}+2W_f=0,}$$ where the energy $E_{kf}=\int A_{\alpha }{j}^{\alpha }\sqrt{-g}d{x}^{1}d{x}^{2}d{x}^3$ considered as the kinetic field energy associated with four-current ${\displaystyle j^{\alpha }}$, and $${\displaystyle W_f=\frac{1}{4{\mu }_0}\int F_{\alpha \beta }{F}^{\alpha \beta }\sqrt{-g}d{x}^{1}d{x}^{2}d{x}^3}$$ sets the potential field energy found through the components of the electromagnetic tensor.

The virial theorem is frequently applied in astrophysics, especially relating the gravitational potential energy of a system to its kinetic or thermal energy. Some common virial relations are Template:Citation needed $${\displaystyle \frac{3}{5}\frac{GM}{R}=\frac{3}{2}\frac{k_{\mathrm{B}}T}{m_{\mathrm{p}}}=\frac{1}{2}{v}^2}$$ for a mass Template:Mvar, radius Template:Mvar, velocity Template:Mvar, and temperature Template:Mvar. The constants are Newton's constant Template:Mvar, the Boltzmann constant Template:Math, and proton mass Template:Math. Note that these relations are only approximate, and often the leading numerical factors (e.g. Template:Sfrac or Template:Sfrac) are neglected entirely.

Template:Main In astronomy, the mass and size of a galaxy (or general overdensity) is often defined in terms of the "virial mass" and "virial radius" respectively. Because galaxies and overdensities in continuous fluids can be highly extended (even to infinity in some models, such as an isothermal sphere), it can be hard to define specific, finite measures of their mass and size. The virial theorem, and related concepts, provide an often convenient means by which to quantify these properties.

In galaxy dynamics, the mass of a galaxy is often inferred by measuring the rotation velocity of its gas and stars, assuming circular Keplerian orbits. Using the virial theorem, the velocity dispersion Template:Mvar can be used in a similar way. Taking the kinetic energy (per particle) of the system as Template:Math, and the potential energy (per particle) as Template:Math we can write

$${\displaystyle \frac{GM}{R}\approx {\sigma }^2.}$$

Here ${\displaystyle R}$ is the radius at which the velocity dispersion is being measured, and Template:Mvar is the mass within that radius. The virial mass and radius are generally defined for the radius at which the velocity dispersion is a maximum, i.e.

$${\displaystyle \frac{G{M}_{\text{vir}}}{R_{\text{vir}}}\approx {\sigma }_{\max }^2.}$$

As numerous approximations have been made, in addition to the approximate nature of these definitions, order-unity proportionality constants are often omitted (as in the above equations). These relations are thus only accurate in an order of magnitude sense, or when used self-consistently.

An alternate definition of the virial mass and radius is often used in cosmology where it is used to refer to the radius of a sphere, centered on a galaxy or a galaxy cluster, within which virial equilibrium holds. Since this radius is difficult to determine observationally, it is often approximated as the radius within which the average density is greater, by a specified factor, than the critical density $${\displaystyle {\rho }_{\text{crit}}=\frac{3H^2}{8\pi G}}$$ where Template:Mvar is the Hubble parameter and Template:Mvar is the gravitational constant. A common choice for the factor is 200, which corresponds roughly to the typical over-density in spherical top-hat collapse (see Virial mass), in which case the virial radius is approximated as $${\displaystyle r_{\text{vir}}\approx r_{200}=r,\rho =200\cdot {\rho }_{\text{crit}}.}$$ The virial mass is then defined relative to this radius as $${\displaystyle M_{\text{vir}}\approx M_{200}=\frac{4}{3}\pi r_{200}^3\cdot 200{\rho }_{\text{crit}}.}$$

The virial theorem is applicable to the cores of stars, by establishing a relation between gravitational potential energy and thermal kinetic energy (i.e. temperature). As stars on the main sequence convert hydrogen into helium in their cores, the mean molecular weight of the core increases and it must contract to maintain enough pressure to support its own weight. This contraction decreases its potential energy and, the virial theorem states, increases its thermal energy. The core temperature increases even as energy is lost, effectively a negative specific heat.^[26] This continues beyond the main sequence, unless the core becomes degenerate since that causes the pressure to become independent of temperature and the virial relation with Template:Mvar equals −1 no longer holds.^[27]

• Virial coefficient
• Virial stress
• Virial mass
• Chandrasekhar tensor
• Chandrasekhar virial equations
• Derrick's theorem
• Equipartition theorem
• Ehrenfest theorem
• Pokhozhaev's identity
• Statistical mechanics

Template:Reflist

• Template:Cite book
• Template:Cite book
• Template:Cite journal

• The Virial Theorem at MathPages
• Gravitational Contraction and Star Formation, Georgia State University