Hamilton–Jacobi equation

In spherical coordinates the Hamiltonian of a free particle moving in a conservative potential U can be written

${\displaystyle H={\frac {1}{2m}}\left[p_{r}^{2}+{\frac {p_{\theta }^{2}}{r^{2}}}+{\frac {p_{\phi }^{2}}{r^{2}\sin ^{2}\theta }}\right]+U(r,\theta ,\phi ).}$

The Hamilton–Jacobi equation is completely separable in these coordinates provided that there exist functions U_r(r), U_θ(θ) and U_ϕ(ϕ) such that U can be written in the analogous form

${\displaystyle U(r,\theta ,\phi )=U_{r}(r)+{\frac {U_{\theta }(\theta )}{r^{2}}}+{\frac {U_{\phi }(\phi )}{r^{2}\sin ^{2}\theta }}.}$

Substitution of the completely separated solution

${\displaystyle S=S_{r}(r)+S_{\theta }(\theta )+S_{\phi }(\phi )-Et}$

into the HJE yields

${\displaystyle {\frac {1}{2m}}\left({\frac {dS_{r}}{dr}}\right)^{2}+U_{r}(r)+{\frac {1}{2mr^{2}}}\left[\left({\frac {dS_{\theta }}{d\theta }}\right)^{2}+2mU_{\theta }(\theta )\right]+{\frac {1}{2mr^{2}\sin ^{2}\theta }}\left[\left({\frac {dS_{\phi }}{d\phi }}\right)^{2}+2mU_{\phi }(\phi )\right]=E.}$

This equation may be solved by successive integrations of ordinary differential equations, beginning with the equation for ${\displaystyle \phi }$

${\displaystyle \left({\frac {dS_{\phi }}{d\phi }}\right)^{2}+2mU_{\phi }(\phi )=\Gamma _{\phi }}$

where ${\displaystyle \Gamma _{\phi }}$ is a constant of the motion that eliminates the ${\displaystyle \phi }$ dependence from the Hamilton–Jacobi equation

${\displaystyle {\frac {1}{2m}}\left({\frac {dS_{r}}{dr}}\right)^{2}+U_{r}(r)+{\frac {1}{2mr^{2}}}\left[\left({\frac {dS_{\theta }}{d\theta }}\right)^{2}+2mU_{\theta }(\theta )+{\frac {\Gamma _{\phi }}{\sin ^{2}\theta }}\right]=E.}$

The next ordinary differential equation involves the ${\displaystyle \theta }$ generalized coordinate

${\displaystyle \left({\frac {dS_{\theta }}{d\theta }}\right)^{2}+2mU_{\theta }(\theta )+{\frac {\Gamma _{\phi }}{\sin ^{2}\theta }}=\Gamma _{\theta }}$

where ${\displaystyle \Gamma _{\theta }}$ is again a constant of the motion that eliminates the ${\displaystyle \theta }$ dependence and reduces the HJE to the final ordinary differential equation

${\displaystyle {\frac {1}{2m}}\left({\frac {dS_{r}}{dr}}\right)^{2}+U_{r}(r)+{\frac {\Gamma _{\theta }}{2mr^{2}}}=E}$

whose integration completes the solution for ${\displaystyle S}$.

The Hamiltonian in elliptic cylindrical coordinates can be written

${\displaystyle H={\frac {p_{\mu }^{2}+p_{\nu }^{2}}{2ma^{2}\left(\sinh ^{2}\mu +\sin ^{2}\nu \right)}}+{\frac {p_{z}^{2}}{2m}}+U(\mu ,\nu ,z)}$

where the foci of the ellipses are located at ${\displaystyle \pm a}$ on the ${\displaystyle x}$-axis. The Hamilton–Jacobi equation is completely separable in these coordinates provided that ${\displaystyle U}$ has an analogous form

${\displaystyle U(\mu ,\nu ,z)={\frac {U_{\mu }(\mu )+U_{\nu }(\nu )}{\sinh ^{2}\mu +\sin ^{2}\nu }}+U_{z}(z)}$

where : ${\displaystyle U_{\mu }(\mu )}$, ${\displaystyle U_{\nu }(\nu )}$ and ${\displaystyle U_{z}(z)}$ are arbitrary functions. Substitution of the completely separated solution

${\displaystyle S=S_{\mu }(\mu )+S_{\nu }(\nu )+S_{z}(z)-Et}$ into the HJE yields

${\displaystyle {\frac {1}{2m}}\left({\frac {dS_{z}}{dz}}\right)^{2}+U_{z}(z)+{\frac {1}{2ma^{2}\left(\sinh ^{2}\mu +\sin ^{2}\nu \right)}}\left[\left({\frac {dS_{\mu }}{d\mu }}\right)^{2}+\left({\frac {dS_{\nu }}{d\nu }}\right)^{2}+2ma^{2}U_{\mu }(\mu )+2ma^{2}U_{\nu }(\nu )\right]=E.}$

Separating the first ordinary differential equation

${\displaystyle {\frac {1}{2m}}\left({\frac {dS_{z}}{dz}}\right)^{2}+U_{z}(z)=\Gamma _{z}}$

yields the reduced Hamilton–Jacobi equation (after re-arrangement and multiplication of both sides by the denominator)

${\displaystyle \left({\frac {dS_{\mu }}{d\mu }}\right)^{2}+\left({\frac {dS_{\nu }}{d\nu }}\right)^{2}+2ma^{2}U_{\mu }(\mu )+2ma^{2}U_{\nu }(\nu )=2ma^{2}\left(\sinh ^{2}\mu +\sin ^{2}\nu \right)\left(E-\Gamma _{z}\right)}$

which itself may be separated into two independent ordinary differential equations

${\displaystyle \left({\frac {dS_{\mu }}{d\mu }}\right)^{2}+2ma^{2}U_{\mu }(\mu )+2ma^{2}\left(\Gamma _{z}-E\right)\sinh ^{2}\mu =\Gamma _{\mu }}$

${\displaystyle \left({\frac {dS_{\nu }}{d\nu }}\right)^{2}+2ma^{2}U_{\nu }(\nu )+2ma^{2}\left(\Gamma _{z}-E\right)\sin ^{2}\nu =\Gamma _{\nu }}$

that, when solved, provide a complete solution for ${\displaystyle S}$.

The Hamiltonian in parabolic cylindrical coordinates can be written

${\displaystyle H={\frac {p_{\sigma }^{2}+p_{\tau }^{2}}{2m\left(\sigma ^{2}+\tau ^{2}\right)}}+{\frac {p_{z}^{2}}{2m}}+U(\sigma ,\tau ,z).}$

The Hamilton–Jacobi equation is completely separable in these coordinates provided that ${\displaystyle U}$ has an analogous form

${\displaystyle U(\sigma ,\tau ,z)={\frac {U_{\sigma }(\sigma )+U_{\tau }(\tau )}{\sigma ^{2}+\tau ^{2}}}+U_{z}(z)}$

where ${\displaystyle U_{\sigma }(\sigma )}$, ${\displaystyle U_{\tau }(\tau )}$, and ${\displaystyle U_{z}(z)}$ are arbitrary functions. Substitution of the completely separated solution

${\displaystyle S=S_{\sigma }(\sigma )+S_{\tau }(\tau )+S_{z}(z)-Et+{\text{constant}}}$

into the HJE yields

${\displaystyle {\frac {1}{2m}}\left({\frac {dS_{z}}{dz}}\right)^{2}+U_{z}(z)+{\frac {1}{2m\left(\sigma ^{2}+\tau ^{2}\right)}}\left[\left({\frac {dS_{\sigma }}{d\sigma }}\right)^{2}+\left({\frac {dS_{\tau }}{d\tau }}\right)^{2}+2mU_{\sigma }(\sigma )+2mU_{\tau }(\tau )\right]=E.}$

Separating the first ordinary differential equation

${\displaystyle {\frac {1}{2m}}\left({\frac {dS_{z}}{dz}}\right)^{2}+U_{z}(z)=\Gamma _{z}}$

yields the reduced Hamilton–Jacobi equation (after re-arrangement and multiplication of both sides by the denominator)

${\displaystyle \left({\frac {dS_{\sigma }}{d\sigma }}\right)^{2}+\left({\frac {dS_{\tau }}{d\tau }}\right)^{2}+2mU_{\sigma }(\sigma )+2mU_{\tau }(\tau )=2m\left(\sigma ^{2}+\tau ^{2}\right)\left(E-\Gamma _{z}\right)}$

which itself may be separated into two independent ordinary differential equations

${\displaystyle \left({\frac {dS_{\sigma }}{d\sigma }}\right)^{2}+2mU_{\sigma }(\sigma )+2m\sigma ^{2}\left(\Gamma _{z}-E\right)=\Gamma _{\sigma }}$

${\displaystyle \left({\frac {dS_{\tau }}{d\tau }}\right)^{2}+2mU_{\tau }(\tau )+2m\tau ^{2}\left(\Gamma _{z}-E\right)=\Gamma _{\tau }}$

that, when solved, provide a complete solution for ${\displaystyle S}$.

The HJE establishes a duality between trajectories and wave fronts.[5] For example, in geometrical optics, light can be considered either as “rays” or waves. The wave front can be defined as the surface ${\textstyle {\cal {C}}_{t}}$ that the light emitted at time ${\textstyle t=0}$ has reached at time ${\textstyle t}$. Light rays and wave fronts are dual: if one is known, the other can be deduced.

More precisely, geometrical optics is a variational problem where the “action” is the travel time ${\textstyle T}$ along a path,

$${\displaystyle T={\frac {1}{c}}\int _{A}^{B}nds}$$

where ${\textstyle n}$ is the medium's index of refraction and ${\textstyle ds}$ is an infinitesimal arc length. From the above formulation, one can compute the ray paths using the Euler-Lagrange formulation; alternatively, one can compute the wave fronts by solving the Hamilton-Jacobi equation. Knowing one leads to knowing the other.

The above duality is very general and applies to all systems that derive from a variational principle: either compute the trajectories using Euler-Lagrange equations or the wave fronts by using Hamilton-Jacobi equation.

The wave front at time ${\textstyle t}$, for a system initially at ${\textstyle {\textbf {q}}_{0}}$ at time ${\textstyle t_{0}}$, is defined as the collection of points ${\textstyle {\textbf {q}}}$ such that ${\textstyle S({\textbf {q}},t)={\text{const}}}$. If ${\textstyle S({\textbf {q}},t)}$ is known, the momentum is immediately deduced,

$${\displaystyle {\textbf {p}}={\frac {\partial S}{\partial {\textbf {q}}}}.}$$

Once ${\textstyle {\textbf {p}}}$ is known, tangents to the trajectories ${\textstyle {\dot {\textbf {q}}}}$ are computed by solving the equation

$${\displaystyle {\frac {\partial {\cal {L}}}{\partial {\dot {\textbf {q}}}}}={\boldsymbol {p}}}$$

for ${\textstyle {\dot {\textbf {q}}}}$, where ${\textstyle {\cal {L}}}$ is the Lagrangian. The trajectories are then recovered from the knowledge of ${\textstyle {\dot {\textbf {q}}}}$.

The isosurfaces of the function ${\displaystyle S({\textbf {q}},t)}$ can be determined at any time t. The motion of an ${\displaystyle S}$-isosurface as a function of time is defined by the motions of the particles beginning at the points ${\displaystyle {\textbf {q}}}$ on the isosurface. The motion of such an isosurface can be thought of as a wave moving through ${\displaystyle {\textbf {q}}}$-space, although it does not obey the wave equation exactly. To show this, let S represent the phase of a wave

${\displaystyle \psi =\psi _{0}e^{iS/\hbar }}$

where ${\displaystyle \hbar }$ is a constant (Planck's constant) introduced to make the exponential argument dimensionless; changes in the amplitude of the wave can be represented by having ${\displaystyle S}$ be a complex number. We may then rewrite the Hamilton–Jacobi equation as

${\displaystyle {\frac {\hbar ^{2}}{2m}}\nabla ^{2}\psi -U\psi ={\frac {\hbar }{i}}{\frac {\partial \psi }{\partial t}}}$

which is the Schrödinger equation.

Conversely, starting with the Schrödinger equation and our ansatz for ${\displaystyle \psi }$, we arrive at[6]

${\displaystyle {\frac {1}{2m}}\left(\nabla S\right)^{2}+U+{\frac {\partial S}{\partial t}}={\frac {i\hbar }{2m}}\nabla ^{2}S.}$

The classical limit (${\displaystyle \hbar \rightarrow 0}$) of the Schrödinger equation above becomes identical to the following variant of the Hamilton–Jacobi equation,

${\displaystyle {\frac {1}{2m}}\left(\nabla S\right)^{2}+U+{\frac {\partial S}{\partial t}}=0.}$

Using the energy–momentum relation in the form[7]

${\displaystyle g^{\alpha \beta }P_{\alpha }P_{\beta }-(mc)^{2}=0}$

for a particle of rest mass ${\displaystyle m}$ travelling in curved space, where ${\displaystyle g^{\alpha \beta }}$are the contravariant coordinates of the metric tensor (i.e., the inverse metric) solved from the Einstein field equations, and ${\displaystyle c}$ is the speed of light. Setting the four-momentum ${\displaystyle P_{\alpha }}$ equal to the four-gradient of the action ${\displaystyle S}$,

${\displaystyle P_{\alpha }=-{\frac {\partial S}{\partial x^{\alpha }}}}$

gives the Hamilton–Jacobi equation in the geometry determined by the metric ${\displaystyle g}$:

${\displaystyle g^{\alpha \beta }{\frac {\partial S}{\partial x^{\alpha }}}{\frac {\partial S}{\partial x^{\beta }}}-(mc)^{2}=0,}$

in other words, in a gravitational field.

For a particle of rest mass ${\displaystyle m}$ and electric charge ${\displaystyle e}$ moving in electromagnetic field with four-potential ${\displaystyle A_{i}=(\phi ,\mathrm {A} )}$ in vacuum, the Hamilton–Jacobi equation in geometry determined by the metric tensor ${\displaystyle g^{ik}=g_{ik}}$ has a form

${\displaystyle g^{ik}\left({\frac {\partial S}{\partial x^{i}}}+{\frac {e}{c}}A_{i}\right)\left({\frac {\partial S}{\partial x^{k}}}+{\frac {e}{c}}A_{k}\right)=m^{2}c^{2}}$

and can be solved for the Hamilton Principal Action function ${\displaystyle S}$ to obtain further solution for the particle trajectory and momentum:[8]

${\displaystyle x=-{\frac {e}{c\gamma }}\int A_{z}\,d\xi ,}$

${\displaystyle y=-{\frac {e}{c\gamma }}\int A_{y}\,d\xi ,}$

${\displaystyle z=-{\frac {e^{2}}{2c^{2}\gamma ^{2}}}\int (\mathrm {A} ^{2}-{\overline {\mathrm {A} ^{2}}})\,d\xi ,}$

${\displaystyle \xi =ct-{\frac {e^{2}}{2\gamma ^{2}c^{2}}}\int (\mathrm {A} ^{2}-{\overline {\mathrm {A} ^{2}}})\,d\xi ,}$

${\displaystyle p_{x}=-{\frac {e}{c}}A_{x}}$, ${\displaystyle p_{y}=-{\frac {e}{c}}A_{y},}$

${\displaystyle p_{z}={\frac {e^{2}}{2\gamma c}}(\mathrm {A} ^{2}-{\overline {\mathrm {A} ^{2}}}),}$

${\displaystyle {\mathcal {E}}=c\gamma +{\frac {e^{2}}{2\gamma c}}(\mathrm {A} ^{2}-{\overline {\mathrm {A} ^{2}}}),}$

where ${\displaystyle \xi =ct-z}$ and ${\displaystyle \gamma ^{2}=m^{2}c^{2}+{\frac {e^{2}}{c^{2}}}{\overline {A}}^{2}}$ with ${\displaystyle {\overline {\mathbf {A} }}}$ the cycle average of the vector potential.

In the case of circular polarization,

${\displaystyle E_{x}=E_{0}\sin \omega \xi _{1}}$, ${\displaystyle E_{y}=E_{0}\cos \omega \xi _{1},}$

${\displaystyle A_{x}={\frac {cE_{0}}{\omega }}\cos \omega \xi _{1}}$, ${\displaystyle A_{y}=-{\frac {cE_{0}}{\omega }}\sin \omega \xi _{1}.}$

Hence

${\displaystyle x=-{\frac {ecE_{0}}{\omega }}\sin \omega \xi _{1},}$

${\displaystyle y=-{\frac {ecE_{0}}{\omega }}\cos \omega \xi _{1},}$

${\displaystyle p_{x}=-{\frac {eE_{0}}{\omega }}\cos \omega \xi _{1},}$

${\displaystyle p_{y}={\frac {eE_{0}}{\omega }}\sin \omega \xi _{1},}$

where ${\displaystyle \xi _{1}=\xi /c}$, implying the particle moving along a circular trajectory with a permanent radius ${\displaystyle ecE_{0}/\gamma \omega ^{2}}$ and an invariable value of momentum ${\displaystyle eE_{0}/\omega ^{2}}$ directed along a magnetic field vector.

For the flat, monochromatic, linearly polarized wave with a field ${\displaystyle E}$ directed along the axis ${\displaystyle y}$

${\displaystyle E_{y}=E_{0}\cos \omega \xi _{1},}$

${\displaystyle A_{y}=-{\frac {cE_{0}}{\omega }}\sin \omega \xi _{1},}$

hence

${\displaystyle x={\text{const}},}$

${\displaystyle y_{0}=-{\frac {ecE_{0}}{\gamma \omega ^{2}}},}$

${\displaystyle y=y_{0}\cos \omega \xi _{1}}$, ${\displaystyle z=C_{z}y_{0}\sin 2\omega \xi _{1},}$

${\displaystyle C_{z}={\frac {eE_{0}}{8\gamma \omega }}}$, ${\displaystyle \gamma ^{2}=m^{2}c^{2}+{\frac {e^{2}E_{0}^{2}}{2\omega ^{2}}},}$

${\displaystyle p_{x}=0,}$

${\displaystyle p_{y,0}={\frac {eE_{0}}{\omega }},}$

${\displaystyle p_{y}=p_{y,0}\sin \omega \xi _{1},}$

${\displaystyle p_{z}=-2C_{z}p_{y,0}\cos 2\omega \xi _{1}}$

implying the particle figure-8 trajectory with a long its axis oriented along the electric field ${\displaystyle E}$ vector.

For the electromagnetic wave with axial (solenoidal) magnetic field:[9]

${\displaystyle E=E_{\phi }={\frac {\omega \rho _{0}}{c}}B_{0}\cos \omega \xi _{1},}$

${\displaystyle A_{\phi }=-\rho _{0}B_{0}\sin \omega \xi _{1}=-{\frac {L_{s}}{\pi \rho _{0}N_{s}}}I_{0}\sin \omega \xi _{1},}$

hence

${\displaystyle x={\text{constant}},}$

${\displaystyle y_{0}=-{\frac {e\rho _{0}B_{0}}{\gamma \omega }},}$

${\displaystyle y=y_{0}\cos \omega \xi _{1},}$

${\displaystyle z=C_{z}y_{0}\sin 2\omega \xi _{1},}$

${\displaystyle C_{z}={\frac {e\rho _{0}B_{0}}{8c\gamma }},}$

${\displaystyle \gamma ^{2}=m^{2}c^{2}+{\frac {e^{2}\rho _{0}^{2}B_{0}^{2}}{2c^{2}}},}$

${\displaystyle p_{x}=0,}$

${\displaystyle p_{y,0}={\frac {e\rho _{0}B_{0}}{c}},}$

${\displaystyle p_{y}=p_{y,0}\sin \omega \xi _{1},}$

${\displaystyle p_{z}=-2C_{z}p_{y,0}\cos 2\omega \xi _{1},}$

where ${\displaystyle B_{0}}$ is the magnetic field magnitude in a solenoid with the effective radius ${\displaystyle \rho _{0}}$, inductivity ${\displaystyle L_{s}}$, number of windings ${\displaystyle N_{s}}$, and an electric current magnitude ${\displaystyle I_{0}}$ through the solenoid windings. The particle motion occurs along the figure-8 trajectory in ${\displaystyle yz}$ plane set perpendicular to the solenoid axis with arbitrary azimuth angle ${\displaystyle \varphi }$ due to axial symmetry of the solenoidal magnetic field.