Dirac operator: Difference between revisions

In mathematics and quantum mechanics, a Dirac operator is a differential operator that is a formal square root, or half-iterate, of a second-order operator such as a Laplacian. The original case which concerned Paul Dirac was to factorise formally an operator for Minkowski space, to get a form of quantum theory compatible with special relativity; to get the relevant Laplacian as a product of first-order operators he introduced spinors.

In general, let ${\displaystyle D}$ be a first-order differential operator acting on a vector bundle ${\displaystyle V}$ over a Riemannian manifold ${\displaystyle M}$.

If

${\displaystyle D^{2}=\Delta ,\,}$

with ${\displaystyle \Delta }$ being the Laplacian of ${\displaystyle V}$, ${\displaystyle D}$ is called a Dirac operator.

In high-energy physics, this requirement is often relaxed: only the second-order part of ${\displaystyle D^{2}}$ must equal the Laplacian.

1. ${\displaystyle -i\partial _{x}}$ is a Dirac operator on the tangent bundle over a line.


2. We now consider a simple bundle of importance in physics: The configuration space of a particle with spin ¹⁄₂ confined to a plane, which is also the base manifold. It's represented by a a wavefunction ψ: R² → C²

   ${\displaystyle {\begin{bmatrix}\chi (x,y)\\\eta (x,y)\end{bmatrix}}}$,
   

   where x and y are the usual coordinate functions on R². χ specifies the probability amplitude for the particle to be in the spin-up state, and similarly for η. The so-called spin-Dirac operator can then be written

   ${\displaystyle D=-i\sigma _{x}\partial _{x}-i\sigma _{y}\partial _{y},\,}$

   where σ_i are the Pauli matrices. Note that the anticommutation relations for the Pauli matrices make the proof of the above defining property trivial. Those relations define the notion of a Clifford algebra. Solutions to the Dirac equation for spinor fields are often called harmonic spinors[1].


3. The most famous Dirac operator describes the propagation of a free fermion in three dimensions and is elegantly written

   ${\displaystyle D=\gamma ^{\mu }\partial _{\mu }\ \equiv \partial \!\!\!/,}$

   using the Feynman slash notation.


4. There is also the Dirac operator arising in Clifford analysis. In euclidean n-space this is

   ${\displaystyle D=\sum _{j=1}^{n}e_{j}{\frac {\partial }{\partial x_{j}}}}$

   where

   ${\displaystyle \{e_{j}:j=1,\ldots ,n\}}$

   is an orthonormal basis for euclidean n-space, and ${\displaystyle \mathbb {R} ^{n}}$ is considered to be embedded in a Clifford algebra. This is a special case of the Atiyah-Singer-Dirac operator acting on sections of a spinor bundle.


5. For a spin manifold, M, the Atiyah-Singer-Dirac operator is locally defined as follows: For ${\displaystyle x\in M}$ and ${\displaystyle e_{1}(x),\ldots ,e_{j}(x)}$ a local orthonormal basis for the tangent space of M at x, the Atiyah-Singer-Dirac operator is

   ${\displaystyle \sum _{j=1}^{n}e_{j}(x){\tilde {\Gamma }}_{e_{j}(x)}}$,

   where ${\displaystyle {\tilde {\Gamma }}}$ is a lifting of the Levi-Civita connection on M to the spinor bundle over M.