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{{Algebra of Physical Space}}
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The [[Dirac equation]], as the [[Theory of relativity|relativistic]] equation that describes
spin 1/2 particles in [[quantum mechanics]] can be written in terms of the [[Algebra of physical space]] (APS), which is a case of a [[Clifford algebra]] or [[geometric algebra]]
that is based in the use of [[paravectors]].
 
The Dirac equation in APS, including the electromagnetic interaction, reads
 
:<math> i \bar{\partial} \Psi\mathbf{e}_3  + e \bar{A} \Psi = m \bar{\Psi}^\dagger  </math>
 
Another form of the Dirac equation in terms of the Space time algebra was given earlier by [[David Hestenes]].  
 
In general, the Dirac equation in the formalism of geometric algebra has the advantage of
providing a direct geometric interpretation.
 
==Relation with the standard form==
 
The [[spinor]] can be written in a null basis as
:<math>
\Psi = \psi_{11} P_3 - \psi_{12} P_3 \mathbf{e}_1 + \psi_{21} \mathbf{e}_1 P_3 +
  \psi_{22} \bar{P}_3,
</math>
such that the representation of the spinor in terms of the [[Pauli matrices]] is
:<math>
\Psi \rightarrow
\begin{pmatrix}
  \psi_{11} & \psi_{12} \\ \psi_{21} & \psi_{22}
\end{pmatrix}
</math>
:<math>
\bar{\Psi}^\dagger \rightarrow
\begin{pmatrix}
  \psi_{22}^* & -\psi_{21}^* \\ -\psi_{12}^* & \psi_{11}^*
\end{pmatrix}
</math>
 
The standard form of the Dirac equation can be recovered by decomposing the spinor in its right and left-handed spinor components, which are extracted with the help of the projector
:<math> P_3 = \frac{1}{2}( 1 + \mathbf{e}_3), </math>
such that
:<math>
  \Psi_L = \bar{\Psi}^\dagger P_3
</math>
:<math>
  \Psi_R = \Psi P_3^{ }
</math>
with the following matrix representation
:<math>
  \Psi_L \rightarrow
  \begin{pmatrix}
  \psi_{22}^* & 0 \\ -\psi_{12}^* & 0
\end{pmatrix}
</math>
:<math>
  \Psi_R \rightarrow
  \begin{pmatrix}
  \psi_{11} & 0 \\ \psi_{21} & 0
\end{pmatrix}
</math>
 
The Dirac equation can be also written as
:<math> i \partial \bar{\Psi}^\dagger \mathbf{e}_3  + e A \bar{\Psi}^\dagger = m \Psi </math>
 
Without electromagnetic interaction, the following equation is obtained from
the two equivalent forms of the Dirac equation
:<math>
\begin{pmatrix}
0 & i \bar{\partial}\\
i \partial & 0
\end{pmatrix}
 
\begin{pmatrix}
  \bar{\Psi}^\dagger P_3  \\ \Psi P_3
\end{pmatrix}
 
= m
\begin{pmatrix}
\bar{\Psi}^\dagger P_3  \\ \Psi P_3
\end{pmatrix}
</math>
 
so that
 
:<math>
\begin{pmatrix}
0 & i \partial_0 + i\nabla \\
i \partial_0 - i \nabla & 0
\end{pmatrix}
 
\begin{pmatrix}
  \Psi_L  \\ \Psi_R
\end{pmatrix}
 
= m
\begin{pmatrix}
\Psi_L  \\ \Psi_R
\end{pmatrix}
</math>
 
or in matrix representation
:<math>
i \left(
\begin{pmatrix}
0 & 1 \\
1 & 0
\end{pmatrix} \partial_0 +
 
\begin{pmatrix}
0 & \sigma \\
-\sigma & 0
\end{pmatrix} \cdot \nabla
\right)
\begin{pmatrix}
\psi_L  \\ \psi_R
\end{pmatrix}
= m
\begin{pmatrix}
\psi_L  \\ \psi_R
\end{pmatrix},
</math>
where the second column of the right and left spinors can be dropped by defining the
single column chiral spinors as
:<math>
  \psi_L \rightarrow
  \begin{pmatrix}
  \psi_{22}^*  \\ -\psi_{12}^*
\end{pmatrix}
</math>
:<math>
  \psi_R \rightarrow
  \begin{pmatrix}
  \psi_{11}  \\ \psi_{21}
\end{pmatrix}
</math>
 
The standard relativistic covariant form of the Dirac equation in the Weyl
representation can be easily identified
<math>
i \gamma^{\mu} \partial_{\mu} \psi = m \psi,
</math>
such that
:<math>
  \psi_= 
  \begin{pmatrix}
  \psi_{22}^*  \\ -\psi_{12}^* \\
  \psi_{11}  \\ \psi_{21}
\end{pmatrix}
</math>
 
Given two spinors <math>\Psi</math> and <math>\Phi</math> in APS and
their respective spinors in the standard form as <math>\psi</math> and
<math>\phi</math>, one can verify the following identity
:<math>
\phi^\dagger \gamma^0 \psi = \langle \bar{\Phi}\Psi +
  (\bar{\Psi}\Phi)^\dagger \rangle_S
</math>,
such that
:<math>
\psi^\dagger \gamma^0 \psi = 2 \langle \bar{\Psi}\Psi \rangle_{S R}
</math>
 
==Electromagnetic gauge==
 
The Dirac equation is invariant under a global right rotation applied
on the spinor of the type
:<math>
  \Psi \rightarrow \Psi^\prime = \Psi R_0
</math>
so that the kinetic term of the Dirac equation transforms as
:<math>
i\bar{\partial} \Psi \mathbf{e}_3 \rightarrow
  i\bar{\partial} \Psi R_0 \mathbf{e}_3 R_0^\dagger R_0 =
  ( i\bar{\partial} \Psi \mathbf{e}_3^\prime ) R_0,
</math>
where we identify the following rotation
:<math>
\mathbf{e}_3 \rightarrow \mathbf{e}_3^\prime = R_0 \mathbf{e}_3 R_0^\dagger
</math>
The mass term transforms as
:<math>
m \overline{\Psi^\dagger} \rightarrow
m \overline{(\Psi R_0)^\dagger} = m \overline{ \Psi^\dagger }R_0,
</math>
so that we can verify the invariance of the form of the Dirac equation.
A more demanding requirement is that the Dirac equation should be
[[local gauge invariance|invariant under a local gauge transformation]] of the type <math>R=\exp(-i e \chi \mathbf{e}_3) </math>
 
In this case, the kinetic term transforms as
:<math>
i\bar{\partial} \Psi \mathbf{e}_3 \rightarrow
(i \bar{\partial} \Psi) R \mathbf{e}_3 + (e\bar{\partial}\chi) \Psi R
</math>,
so that the left side of the Dirac equation transforms covariantly as
:<math>
i\bar{\partial} \Psi \mathbf{e}_3 -e \bar{A}\Psi \rightarrow
(i\bar{\partial} \Psi R \mathbf{e}_3 R^\dagger -e \overline{(A + \partial \chi)}\Psi)R,
</math>
where we identify the need to perform an electromagnetic gauge transformation.
The mass term transforms as in the case with global rotation, so, the form
of the Dirac equation remains invariant.
 
==Current==
The current is defined as
:<math>
J = \Psi\Psi^\dagger,
</math>
which satisfies the continuity equation
 
:<math>
\left\langle \bar{\partial} J \right\rangle_{S}=0
</math>
 
==Second order Dirac equation==
An application of the Dirac equation on itself leads to the second order Dirac equation
:<math>
(-\partial \bar{\partial} +
A \bar{A}) \Psi - i( 2e\left\langle A \bar{\partial} \right\rangle_S + eF) \Psi \mathbf{e}_3 = m^2 \Psi
</math>
 
==Free particle solutions==
===Positive energy solutions===
A solution for the free particle with momentum <math> p = p^0 + \mathbf{p} </math> and positive energy <math>p^0>0</math> is
 
:<math>
\Psi = \sqrt{\frac{p}{m}} R(0) \exp(-i\left\langle p \bar{x}\right\rangle_S  \mathbf{e}_3).  
</math>
 
This solution is unimodular
:<math>
\Psi \bar{\Psi} = 1
</math>
 
and the current resembles the classical proper velocity
:<math>u = \frac{p}{m} </math>
:<math>
J = \Psi {\Psi}^\dagger = \frac{p}{m}
</math>
 
===Negative energy solutions===
A solution for the free particle with negative energy and momentum
<math> p = -|p^0| - \mathbf{p} = - p^\prime</math> is
 
:<math>
\Psi = i\sqrt{\frac{p^\prime}{m}} R(0) \exp(i\left\langle p^\prime \bar{x}\right\rangle_S  \mathbf{e}_3) ,
</math>
 
This solution is anti-unimodular
:<math>
\Psi \bar{\Psi} = -1
</math>
 
and the current resembles the classical proper velocity <math>u = \frac{p}{m} </math>
:<math>
J = \Psi {\Psi}^\dagger = -\frac{p}{m},
</math>
but with a remarkable feature: "the time runs backwards"
:<math>
\frac{d t}{d \tau} = \left\langle \frac{p}{m}  \right\rangle_S < 0
</math>
 
==Dirac Lagrangian==
The Dirac Lagrangian is
:<math> L =
\langle i \partial \bar{\Psi}^\dagger \mathbf{e}_3 \bar{\Psi}
- e A  \bar{\Psi}^\dagger \bar{\Psi} -m \Psi \bar{\Psi}
\rangle_0 </math>
 
==See also==
 
*[[Paravector]]
*[[Algebra of physical space]]
*[[Geometric algebra]]
*[[Two-body Dirac equations]]
 
==References==
===Textbooks===
* Baylis, William (2002). ''Electrodynamics: A Modern Geometric Approach'' (2nd ed.). Birkhäuser. ISBN 0-8176-4025-8
 
* W. E. Baylis, editor, ''Clifford (Geometric) Algebra with Applications to Physics, Mathematics, and Engineering'', Birkhäuser, Boston 1996.
 
===Articles===
* Baylis, William, ''Classical eigenspinors and the Dirac equation'', [http://prola.aps.org/abstract/PRA/v45/i7/p4293_1 Phys. Rev. A 45, 4293–4302] (1992)
 
* [[David Hestenes|Hestenes]] D., ''Observables, operators, and complex numbers in the Dirac theory'', [[Journal of Mathematical Physics|J. Math. Phys.]] 16, 556 (1975)
 
 
[[Category:Quantum mechanics]]
[[Category:Quantum field theory]]
[[Category:Spinors]]
[[Category:Equations of physics]]
[[Category:Paul Dirac|Equation in the algebra of physical space]]
[[Category:Dirac equation|Algebra of physical space]]

Latest revision as of 23:34, 26 June 2014

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