## Sunday, September 23, 2012

### The maximal Gordon decomposition

We present a novel and elegant expression for the maximal Gordon composition for an electron field that can vary locally in all of it's 16 field description parameters.

The 16 bilinear Dirac field components

The fully extended Gordon decomposition provides a powerful tool to obtain a thorough understanding of the fundamental behavior of the interacting electron and in general the interacting fermion described by the Dirac equation. I turns out that, despite the long and painstaking calculations, all the results can be arranged in a compact manner which is easy accessible for interpretation. We'll apply the decomposition on all the Dirac bilinear fields (16 components in total)

The bilinear Dirac fields

\begin{aligned} &&\mbox{Scalar}~~~~ && ~~\bar{\psi}\psi & ~~~~~~~~\mbox{1 component} \\ &&\mbox{Vector}~~~~ && ~~\bar{\psi}\gamma^\mu\psi & ~~~~~~~~\mbox{4 components} \\ &&\mbox{Antisym.Tensor}~~~~&& ~~\bar{\psi}\sigma^{\mu\nu}\psi & ~~~~~~~~\mbox{6 components} \\ &&\mbox{Axial vector}~~~~ && ~~\bar{\psi}\gamma^\mu\gamma^5\psi & ~~~~~~~~\mbox{4 components} \\ &&\mbox{Pseudo scalar}~~~~ && ~i\bar{\psi}\gamma^5\psi & ~~~~~~~~\mbox{1 component} \\ \end{aligned}

These fields are, due to their Lorentz transform, associated with: The invariant mass (scalar), The charge/current density (vector), the spin density (axial vector) and the magnetization/polarization tensor.

The 16 fermion field description parameters

By applying the decomposition we determine how these fields depend on the first order derivatives of, not only, the magnitude and phase of the field but on how they depend on the first order derivatives of a systematically complete set of 16 field description parameters including for instance the local rotation and local boost of the field.The Magnitude, Phase, Balance and Phase skew are the single component field descriptors which transform like Lorentz scalars. The Boost, Rotation, Magnetization and Polarization are all 3-component field descriptors which transform like tensor fields. The generators of the 16 fermion field description parameters and their relations can be compactly defined by.

The field description parameters
\begin{aligned} &\mbox{Magnitude:} &{\mbox{\tfrac12\left(\!\begin{array}{r} \sigma^o~~~~0~~ \\ 0~~~~~~\sigma^o \end{array}\!\!\!\right)$}}~~~~~~~~ &\mbox{Magnetization:} &{\mbox{$-\tfrac12\left(\!\begin{array}{r} \vec{\sigma}~~~~~~0 \\ 0~~~~~~\vec{\sigma} \end{array}\!\right)$}} \\ \\ &\mbox{Phase:} &{\mbox{$\tfrac12\left(\!\begin{array}{r} i\sigma^o~~~0~~ \\ 0~~~~i\sigma^o  \end{array}\!\!\!\right)$}}~~~~~~~~ &\mbox{Rotation:} &{\mbox{$-\tfrac12\left(\!\begin{array}{r} i\vec{\sigma}~~~~~0 \\ 0~~~~i\vec{\sigma}  \end{array}\!\right)$}} \\ \\ &\mbox{Balance:} &{\mbox{$\tfrac12\left(\!\begin{array}{r} \sigma^o~~~~0~~ \\ 0~~~-\!\sigma^o \end{array}\!\!\!\right)$}}~~~~~~~~ &\mbox{Boost:} &{\mbox{$-\tfrac12\left(\!\begin{array}{r} \vec{\sigma}~~~~~~0 \\ 0~~~-\!\vec{\sigma} \end{array}\!\right)$}} \\ \\ &\mbox{Phase skew:} &{\mbox{$\tfrac12\left(\!\begin{array}{r} i\sigma^o~~~0~~ \\ 0~-\!i\sigma^o \end{array}\!\!\!\right)$}}~~~~~~~~ &\mbox{Polarization:} &{\mbox{$-\tfrac12\left(\!\begin{array}{r} i\vec{\sigma}~~~~~0 \\ 0~-\!i\vec{\sigma} \end{array}\!\right)}} \end{aligned}

The single component field descriptors are associated with $\sigma^o$ while the 3-component field descriptors are associated with the spatial matrices $\vec{\sigma}$. All generators of the set, acting in spinor space, are systematically scaled with the same factor 1/2 familiar from the boost and rotation generators. This means they are scaled to express their effect in Minkowsky space. The Magnetization and Polarization generators are the same as those from the $\sigma^{\mu\nu}$ tensor. The Phase skew generator occurs in Electroweak interactions where the intermediate vector boson fields act asymmetrically on the left and right chiral components $\psi_L$ and $\psi_R$

The Gordon decomposition method

The expressions for the bilinear fields do not contain any partial differentials. It is the Dirac equation which links the values of these fields to the first order differentials of the field. We write the Dirac equation like this,

$\psi_L ~~=~~\tfrac{\hbar}{mc}(~i \,\sigma^\nu \,\partial_\nu ~)\,\psi_R ~~~~~~~~~~ \psi_R ~~=~~\tfrac{\hbar}{mc}(~i \,\tilde{\sigma}^\nu\,\partial_\nu ~)\,\psi_L$

to show us how to substitute $\psi_L$ and $\psi_R$ by differentiated terms. We then take the bilinear product terms and substitute both $\psi^*$ and $\psi$ one at a time and average the results, for instance.

\begin{aligned} \psi_R^*\psi_L \longrightarrow ~~\tfrac12\,\tfrac{\hbar}{mc} \Big( ~[~i \,\tilde{\sigma}^\nu \,\partial_\nu ~\psi_L]^*\psi_L ~~+~~ \psi_R^*[~i \,\sigma^\nu\,\partial_\nu ~\psi_R]~ \Big) \\ \psi_L^*\psi_R \longrightarrow ~~\tfrac12\,\tfrac{\hbar}{mc} \Big( ~[~i \,\sigma^\nu \,\partial_\nu ~\psi_R]^*\psi_R ~~+~~ \psi_L^*[~i \,\tilde{\sigma}^\nu\,\partial_\nu ~\psi_L]~ \Big) \end{aligned}

Then we consider $\psi_L$ and $\psi_R$ as exponentials $\exp (\hat{G}\cdot \mathcal{G})$ of the whole set of generators $\hat{G}$ defined above. We can now define $\partial_\mu\psi_L$ and $\partial_\mu\psi_R$ as a function of the first order derivatives $\partial_\mu\mathcal{G}$ of the field description parameters $\mathcal{G}$ associated with the set of generators $\hat{G}$. When we apply this on all Dirac bilinears we can reorganize the results to obtain the following result.

The results of the complete Gordon decomposition

\begin{aligned} &\tfrac{2mc}{\hbar}~\bar{\psi}\psi &=&- &\bar{\psi}\gamma^\mu\psi~~\Big(~\partial_\mu\,\phi~\,-~\partial_\alpha\, \overset{\hspace{-6pt}\star}{{\cal P}^\alpha_{~\mu}}~\, \Big) && \mbox{Phase} \\ & &&+~~ &\bar{\psi}\gamma^\mu\gamma^5\psi~~\Big(~\partial_\mu\,{\cal P}~-~\partial_\alpha\,\overset{\hspace{-6pt}\star}{J^{\alpha}_{~\mu}}~~ \Big) && \mbox{Phase skew} \\ \\ &\tfrac{2mc}{\hbar}~\bar{\psi}\gamma^\mu\psi &=&+ &\bar{\psi} \sigma^{\mu\nu}\psi~~\Big(~\partial_\nu {\cal M}\,+~\partial_\alpha\,J^{\alpha}_{~\nu}~~ \Big) && \mbox{Magnitude} \\ & &&-~~ &\bar{\psi}\psi~~\Big(~\partial^\mu\,\phi~\,-~\partial_\alpha \overset{\hspace{-6pt}\star}{{\cal P}^{\alpha\mu}}~ \Big) && \mbox{Phase} \\ & &&-~~ & i\bar{\psi}\gamma^5\psi~~\Big(~\partial^\mu\,\vartheta~\,+~\partial_\alpha {\cal P}^{\alpha\mu}~ \Big) && \mbox{Balance} \\ & &&+~~ & \bar{\psi}\overset{\hspace{-9pt}\star}{\sigma^{\mu\nu}}\psi~~\Big(~\partial_\nu\,{\cal P}~-~\partial_\alpha\,\overset{\hspace{-6pt}\star}{J^{\alpha}_{~\nu}}~~ \Big) && \mbox{Phase skew} \\ \\ &\tfrac{2mc}{\hbar}~\bar{\psi}\sigma^{\mu\nu}\psi &=&- &\bar{\psi}\gamma^\mu\psi\,\bigcirc\hspace{-10.40pt}\wedge~\Big(~\partial^\nu {\cal M} +~\partial_\alpha\,J^{\alpha\nu}~ \Big) && \mbox{Magnitude} \\ & &&-~~ &\bar{\psi}\gamma^\mu\gamma^5\psi\,\overset{\hspace{+2pt}\star}{\bigcirc\hspace{-10.3pt}\wedge}\, \Big(~\partial^\nu\,\phi~\,-~\partial_\alpha \overset{\hspace{-6pt}\star}{{\cal P}^{\alpha\nu}}~ \Big) && \mbox{Phase} \\ & &&+~~ &\bar{\psi}\gamma^\mu\gamma^5\psi\,\bigcirc\hspace{-10.30pt}\wedge~ \Big(~\partial^\nu\,\vartheta~\,+~\partial_\alpha {\cal P}^{\alpha\nu}~ \Big) && \mbox{Balance} \\ & &&+~~ &\bar{\psi}\gamma^\mu\psi\,\overset{\hspace{+2pt}\star}{\bigcirc\hspace{-10.4pt}\wedge}\, \Big(~\partial^\nu\,{\cal P}~-~\partial_\alpha\, \overset{\hspace{-6pt}\star}{J^{\alpha\nu}}~ \Big) && \mbox{Phase skew} \\ \\ &\tfrac{2mc}{\hbar}~\bar{\psi}\gamma^\mu\gamma^5\psi &=&- &i\bar{\psi}\gamma^5\psi~~\Big(~\partial^\mu {\cal M} +~\partial_\alpha\,J^{\alpha\mu}~ \Big) && \mbox{Magnitude} \\ & &&+~~ & \bar{\psi}\overset{\hspace{-9pt}\star}{\sigma^{\mu\nu}}\psi~~\Big(~\partial_\nu\,\phi~\,-~\partial_\alpha\, \overset{\hspace{-6pt}\star}{{\cal P}^\alpha_{~\nu}}~\, \Big) && \mbox{Phase} \\ & &&+~~ &\bar{\psi}\sigma^{\mu\nu}\psi~~\Big(~\partial_\nu\,\vartheta~\,+~\partial_\alpha\, {\cal P}^\alpha_{~\nu} ~\, \Big) && \mbox{Balance} \\ & &&-~~ &\bar{\psi}\psi~~\Big(~\partial^\mu\,{\cal P}~-~\partial_\alpha\, \overset{\hspace{-6pt}\star}{J^{\alpha\mu}}~ \Big) && \mbox{Phase skew} \\ \\ &\tfrac{2mc}{\hbar}~i\bar{\psi}\gamma^5\psi &=&+ &\bar{\psi}\gamma^\mu\gamma^5\psi~~\Big(~\partial_\mu {\cal M}\,+~\partial_\alpha\,J^{\alpha}_{~\mu}~~ \Big) && \mbox{Magnitude} \\ & &&-~~ &\bar{\psi}\gamma^\mu\psi~~\Big(~\partial_\mu\,\vartheta~\,+~\partial_\alpha\, {\cal P}^\alpha_{~\mu} ~\, \Big) && \mbox{Balance} \end{aligned}

For a complete description of this Gordon decomposition and the contents of the components of this expression you can download the PDF.

## Saturday, September 22, 2012

### Real Symmetric representation of Dirac's equation

We describe how one can transform the standard representation of the Dirac equation into a new, spatially symmetric, real valued representation. It is shown that this new representation can be used as a direct replacement in QED and other standard model applications, it produces the same results and the notation is carefully chosen to be virtually identical.

The spatial symmetry of the 8 field parameters.

One major consequence of the spatial symmetry is that the 8 field parameters get a spatial symmetric interpretation as well. The cube as seen in the illustrations occurs if we apply the so called "current" operator to the individual field parameters. Each parameter becomes associated with a propagation (current) from the center of the cube to one of the 8 vertices. Each of the 4 central axis of the cube has two of them, one is left circular polarized and the other is right circular polarized. The eight parameters together define the direction of the electron's current density as well as the direction of the electron's spin. Note that 4  axis- orientations are used to define directions instead of the usual 3 spatial coordinates. This means that there is a one parameter redundancy in the definitions. This redundant parameter turns out to be the phase of the wave function. It's the phase of the wave function which enables the interference of matter waves. We have found a way in which nature can define a phase without needing a special preferred direction of rotation. The 720 degrees of spinor rotation.

One of the most puzzling statements a student gets to hear is that "an electron has to rotate over 720 degrees before it returns back to its original position". This statement is directly related to another statement which says that the electron is a spin 1/2 particle. All kinds of strange and often irrelevant visualizations are used by people who are trying to make sense of this. It turns out that we can find the mathematics corresponding to this spin 1/2 behavior directly in the representation itself. We'll see that a more appropriate form of the 720 degrees statement is that "the phase difference is always 1/2 of the geometrical angle"

The electron and positron eigenstates.

We can calculate the eigenstates of the electron (and the positron) directly from the equation of motion. The particles oscillate with a frequency proportional to their mass. If we look at the parameters along, for instance, the x-axis (in case of a spin in the x direction)  then we see that there are 45 degrees phase relations between parameters that are 90 degrees rotated from each other. The images above show 4 parameters with phase shifts of 0, 45, 90 and 135 degrees. The other 4 parameters (in the positron case) have phase shifts of 180, 225, 270 and 315 degrees. In the case of the electron there are extra signs. This is what distinguishes the negative charge from the positive charge.

The rotation generators of spin 1/2 particles.

We can find the mathematical origin of this spin 1/2 behavior (or 720 degrees behavior) directly in the matrices used in the representation. We can rotate the current and spin direction of the electron field with the use of the x, y and z-rotation matrices shown below. Generally when we perform a continuous rotation then we operate on two (orthogonal) components so that these get a 90 degrees sine-cosine relation. The result is then a circular motion. In the real, symmetric representation however we operate on two parameters which are not orthogonal (90 degrees) but diagonally positioned (180 degrees). The result is that the phase difference is 1/2 of the geometrical angle as is typical for a spin 1/2 particle. One can see that each rotation matrix defines four such connections, each time between two parameters. This is why there are four lines shown in each of the images (two X's) The signs in the matrices are so that all four rotations are defined as being in the same direction.

The charge generators of spin 1/2 particles.

If we place the electron in a potential field then its phase change rate will become higher if the electron's energy becomes higher and lower when the energy becomes lower. If we rotate an electron then we will also change the phase of the parameters (by 1/2 the rate). However if we give the electron a different phase change rate by placing it in a constant potential field then we won't rotate the direction of the spin or the current, now, what is the difference mathematically? We see in the image below that the individual components of the charge generator (which is used to describe the influence of the potential field) are almost identical to the rotation generators. The difference is in the signs.  Two of the four connections are now opposite in sign. The result is that the net rotation is zero. The complete charge generator shown at the bottom is symmetric in x, y and z: The electric potential field has no preferred direction in space.

The boost generators of spin 1/2 particles.

If we boost a particle then we accelerate the particle to a different speed. The matrices used for this operation are the boost matrices. These matrices are somewhat more complex but from the images we can see that they correspond to the x, y and z-directions. The most important difference with the rotation matrices is that they are non-zero on the diagonals. This causes some parameters to become bigger and bigger when the boost becomes larger, while other parameters become smaller and smaller. the +1's found on the diagonals correspond to the increasing parameters and the -1's  correspond to decreasing parameters. The parameters that become bigger are drawn with lighter colors while the ones that become smaller are darker. Now, each parameter corresponds with a current in its direction, from the center of the cube outward. If we boost the electron in a certain direction then we indeed expect the currents in that direction to increase while the currents in the opposite direction should decrease.

The mass coupling of the chiral states.

If we don't place the electron in a potential field then we still expect that its phase changes continuously and it should do so with a frequency proportional to its mass. The matrix which is responsible for this is the "mass coupling" matrix. This is the matrix which couples the four left chiral parameters with the four right chiral parameters. It is the only matrix which does so. If we compare the 3 individual components of the mass coupling below with the 3 individual components of the charge generator above, then we see that they have the same 4x4 sub matrices but in different quadrants. This means that the mass coupling has the same effect as the charge generator when the four left chiral parameters are equal to the four right chiral parameters, and the opposite effect if there is a minus sign between the two chiral sets. This is the case in the electron and positron eigenstates respectively. The combined mass coupling matrix is symmetric in x, y and z. Mass does not have a preferred direction in space just like charge doesn't have a preferred direction.