Lévy-Leblond equation

In quantum mechanics, the Lévy-Leblond equation describes the dynamics of a spin-1/2 particle. It is a linearized version of the Schrödinger equation and of the Pauli equation. It was derived by French physicist Jean-Marc Lévy-Leblond in 1967.^[1]

Lévy-Leblond equation was obtained under similar heuristic derivations as the Dirac equation, but contrary to the latter, Lévy-Leblond equation is not relativistic. As both equations recover the electron gyromagnetic ratio, it is suggested that spin is not necessarily a relativistic phenomenon.

Equation[edit]

For a nonrelativistic spin-1/2 particle of mass m, a representation of the time-independent Lévy-Leblond equation reads:^[1]

${\displaystyle \left\{{\begin{matrix}E\psi +({\boldsymbol {\sigma }}\cdot \mathbf {p} c)\chi =0\\({\boldsymbol {\sigma }}\cdot \mathbf {p} c)\psi +2mc^{2}\chi =0\end{matrix}}\right.}$

where c is the speed of light, E is the nonrelativistic particle energy, ${\displaystyle \mathbf {p} =-i\hbar \nabla }$ is the momentum operator, and ${\displaystyle {\boldsymbol {\sigma }}=(\sigma _{x},\sigma _{y},\sigma _{z})}$ is the vector of Pauli matrices, which is proportional to the spin operator ${\displaystyle \mathbf {S} ={\tfrac {1}{2}}\hbar {\boldsymbol {\sigma }}}$. Here ${\displaystyle \psi ,\chi }$ are two components functions (spinors) describing the wave function of the particle.

By minimal coupling, the equation can be modified to account for the presence of an electromagnetic field,^[1]

${\displaystyle \left\{{\begin{matrix}(E-qV)\psi +[{\boldsymbol {\sigma }}\cdot (\mathbf {p} -q\mathbf {A} )c]\chi =0\\{[{\boldsymbol {\sigma }}\cdot (\mathbf {p} -q\mathbf {A} )c]}\psi +2mc^{2}\chi =0\end{matrix}}\right.}$

where q is the electric charge of the particle. V is the electric potential, and A is the magnetic vector potential. This equation is linear in its spatial derivatives.

Relation to spin[edit]

In 1928, Paul Dirac linearized the relativistic dispersion relation and obtained Dirac equation, described by a bispinor. This equation can be decoupled into two spinors in the non-relativistic limit, leading to predict the electron magnetic moment with a gyromagnetic ratio ${\textstyle g=2}$.^[2] The success of Dirac theory has led to some textbooks to erroneously claim that spin is necessarily a relativistic phenomena.^[3][4]

Jean-Marc Lévy-Leblond applied the same technique to the non-relativistic energy relation showing that the same prediction of ${\textstyle g=2}$ can be obtained.^[2] Actually to derive the Pauli equation from Dirac equation one has to pass by Lévy-Leblond equation.^[2] Spin is then a result of quantum mechanics and linearization of the equations but not necessarily a relativistic effect.^[3][5]

Lévy-Leblond equation is Galilean invariant. This equation demonstrates that one does not need the full Poincaré group to explain the spin 1/2.^[4] In the classical limit where ${\textstyle c\to \infty }$, quantum mechanics under the Galilean transformation group are enough.^[1] Similarly, one can construct classical linear equation for any arbitrary spin.^[1][6] Under the same idea one can construct equations for Galilean electromagnetism.^[1]

Relation to other equations[edit]

Schrödinger's and Pauli's equation[edit]

Taking the second line of Lévy-Leblond equation and inserting it back into the first line, one obtains through the algebra of the Pauli matrices, that^[3]

${\displaystyle {\frac {1}{2m}}({\boldsymbol {\sigma }}\cdot \mathbf {p} )^{2}\psi -E\psi =\left[{\frac {1}{2m}}\mathbf {p} ^{2}-E\right]\psi =0}$,

which is the Schrödinger equation for a two-valued spinor. Note that solving for ${\displaystyle \chi }$ also returns another Schrödinger's equation. Pauli's expression for spin-1⁄2 particle in an electromagnetic field can be recovered by minimal coupling:^[3]

${\displaystyle \left\{{\frac {1}{2m}}[{\boldsymbol {\sigma }}\cdot (\mathbf {p} -q\mathbf {A} )]^{2}+qV\right\}\psi =E\psi }$.

While Lévy-Leblond is linear in its derivatives, Pauli's and Schrödinger's equations are quadratic in the spatial derivatives.

Dirac equation[edit]

Dirac equation can be written as:^[1]

${\displaystyle \left\{{\begin{matrix}({\mathcal {E}}-mc^{2})\psi +({\boldsymbol {\sigma }}\cdot \mathbf {p} c)\chi =0\\({\boldsymbol {\sigma }}\cdot \mathbf {p} c)\psi +({\mathcal {E}}+mc^{2})\chi =0\end{matrix}}\right.}$

where ${\textstyle {\mathcal {E}}}$ is the total relativistic energy. In the non-relativistic limit, ${\textstyle E\ll mc^{2}}$ and ${\textstyle {\mathcal {E}}\approx mc^{2}+E+\cdots }$ one recovers, Lévy-Leblond equations.

Heuristic derivation[edit]

Similar to the historical derivation of Dirac equation by Paul Dirac, one can try to linearize the non-relativistic dispersion relation ${\textstyle E={\frac {\mathbf {p} ^{2}}{2m}}}$. We want two operators Θ and Θ' linear in ${\textstyle \mathbf {p} }$ (spatial derivatives) and E, like^[3]

${\displaystyle \left\{{\begin{matrix}\Theta \Psi =[AE+\mathbf {B} \cdot \mathbf {p} c+2mc^{2}C]\Psi =0\\\Theta '\Psi =[A'E+\mathbf {B} '\cdot \mathbf {p} c+2mc^{2}C']\Psi =0\end{matrix}}\right.}$

for some ${\textstyle A,A',\mathbf {B} =(B_{x},B_{y},B_{z}),\mathbf {B} '=(B_{x}',B_{y}',B_{z}'),C,C'}$, such that, their product recovers the classical dispersion relation, that is

${\displaystyle {\frac {1}{2mc^{2}}}\Theta '\Theta =E-{\frac {\mathbf {p} ^{2}}{2m}}}$,

where the factor 2mc² is arbitrary an it is just there for normalization. By doing carrying out the product, one find that there is not solution if ${\textstyle A,A',B_{i},B_{i}',C,C'}$ are one dimensional constants. The lowest dimension where there is a solution is 4. Then ${\textstyle A,A',\mathbf {B} ,\mathbf {B} ',C,C'}$ are matrices that must satisfy the following relations:

${\displaystyle \left\{{\begin{matrix}A'A=0\\C'C=0\\A'B_{i}+B_{i}'A=0\\C'B_{i}+B_{i}'C=0\\A'C+C'A=I_{4}\\B_{i}'B_{j}+B_{j}'B_{i}=-2\delta _{ij}\end{matrix}}\right.}$

these relations can be rearranged to involve the gamma matrices from Clifford algebra.^[3][2] ${\textstyle I_{N}}$ is the Identity matrix of dimension N. One possible representation is

${\displaystyle A=A'={\begin{pmatrix}0&0\\I_{2}&0\end{pmatrix}},B_{i}=-B_{i}'={\begin{pmatrix}\sigma _{i}&0\\0&\sigma _{i}\end{pmatrix}},C=C'={\begin{pmatrix}0&I_{2}\\0&0\end{pmatrix}}}$,

such that ${\textstyle \Theta \Psi =0}$, with ${\textstyle \Psi =(\psi ,\chi )}$ , returns Lévy-Leblond equation. Other representations can be chosen leading to equivalent equations with different signs or phases.^[2][3]

References[edit]