See main article: Quantum field theory in curved spacetime.
In mathematical physics, the Dirac equation in curved spacetime is a generalization of the Dirac equation from flat spacetime (Minkowski space) to curved spacetime, a general Lorentzian manifold.
In full generality the equation can be defined on
M
(M,g)
(-+++)
g
gab
We use a set of vierbein or frame fields
\{e\mu\}=\{e0,e1,e2,e3\}
M
gab
| a | |
| e | |
| \mu |
| b | |
| e | |
| \nu |
=η\mu\nu.
The vierbein defines a local rest frame, allowing the constant Gamma matrices to act at each spacetime point.
In differential-geometric language, the vierbein is equivalent to a section of the frame bundle, and so defines a local trivialization of the frame bundle.
To write down the equation we also need the spin connection, also known as the connection (1-)form. The dual frame fields
\{e\mu\}
| \mu | |
| e | |
| a |
| a | |
| e | |
| \nu |
=
| \mu{} | |
| \delta | |
| \nu. |
| \mu{} | |
| \omega | |
| \nua |
:=
| \mu | |
| e | |
| b\nabla |
a
| b | |
| e | |
| \nu |
\nablaa
One should be careful not to treat the abstract Latin indices and Greek indices as the same, and further to note that neither of these are coordinate indices: it can be verified that
| \mu{} | |
| \omega | |
| \nua |
Mathematically, the frame fields
\{e\mu\}
p
TpM
R1,3
R1,3
Raising and lowering indices is done with
gab
η\mu\nu
The connection form can be viewed as a more abstract connection on a principal bundle, specifically on the frame bundle, which is defined on any smooth manifold, but which restricts to an orthonormal frame bundle on pseudo-Riemannian manifolds.
The connection form with respect to frame fields
\{e\mu\}
See also: Dirac algebra.
\{\gamma\mu\}
\{\gamma\mu,\gamma\nu\}=2η\mu\nu
\{ ⋅ , ⋅ \}
They can be used to construct a representation of the Lorentz algebra: defining
\sigma\mu\nu=-
| i | |
| 4 |
[\gamma\mu,\gamma\nu]=-
| i | |
| 2 |
\gamma\mu\gamma\nu+
| i | |
| 2 |
η\mu\nu
[ ⋅ , ⋅ ]
It can be shown they satisfy the commutation relations of the Lorentz algebra:
[\sigma\mu\nu,\sigma\rho\sigma]=(-i)(\sigma\mu\sigmaη\nu\rho-\sigma\nu\sigmaη\mu\rho+\sigma\nu\rhoη\mu\sigma-\sigma\mu\rhoη\nu\sigma)
They therefore are the generators of a representation of the Lorentz algebra
ak{so}(1,3)
SO(1,3)
ak{so}(3)
SO(3)
Spin(1,3).
The representation space is isomorphic to
C4
| \left( | 1 | ,0\right) ⊕ \left(0, |
| 2 |
| 1 | |
| 2 |
\right)
The abuse of terminology extends to forming this representation at the group level. We can write a finite Lorentz transformation on
R1,3
| \rho | |
| Λ | |
| \sigma |
=\exp\left(
| i | |
| 2 |
\alpha\mu\nuM\mu\nu
| \rho | |
| \right){} | |
| \sigma |
M\mu\nu
(M\mu\nu
| \rho | |
| ) | |
| \sigma |
=η\mu\rho
| \nu | |
| \delta | |
| \sigma |
-η\nu\rho
| \mu | |
| \delta | |
| \sigma |
+1
\mu,\nu
-1
\nu,\mu
If another representation
\rho
T\mu\nu=\rho(M\mu\nu),
| i | |
| \rho(Λ) | |
| j |
=\exp\left(
| i | |
| 2 |
\alpha\mu\nuT\mu\nu
| i | |
| \right){} | |
| j |
i,j
In the case
T\mu\nu=\sigma\mu\nu
\alpha\mu\nu
| \rho | |
| Λ | |
| \sigma |
\rho(Λ)
\alpha\mu\nu,\beta\mu\nu
| \rho | |
| Λ | |
| \sigma |
| i | |
| \rho(Λ) | |
| j. |
Given a coordinate frame
{\partial\alpha}
\{x\alpha\}
\{e\mu\}
\partial\mu\psi=
| \alpha | |
| e | |
| \mu\partial |
\alpha\psi,
| \mu{} | |
| \omega | |
| \nu\rho |
=
| \mu{} | |
| e | |
| \nu\alpha |
.
These components do not transform tensorially under a change of frame, but do when combined. Also, these are definitions rather than saying that these objects can arise as partial derivatives in some coordinate chart. In general there are non-coordinate orthonormal frames, for which the commutator of vector fields is non-vanishing.
It can be checked that under the transformation
\psi\mapsto\rho(Λ)\psi,
D\mu\psi=\partial\mu\psi+
| 1 | |
| 2 |
(\omega\nu\rho)\mu\sigma\nu\rho\psi
D\mu\psi
D\mu\psi\mapsto\rho(Λ)D\mu\psi
This generalises to any representation
R
v
D\muv=\partial\muv+
| 1 | |
| 2 |
(\omega\nu\rho)\muR(M\nu\rho)v=\partial\muv+
| 1 | |
| 2 |
(\omega\nu\rho)\muT\nu\rhov.
R
SO(1,3)
There are some subtleties in what kind of mathematical object the different types of covariant derivative are. The covariant derivative
D\alpha\psi
p
Ep ⊗
| * | |
| T | |
| pM |
D\mu\psi
\{e\mu\}
p
Ep ⊗ R1,3,
{R1,3
\gamma\mu
p
End(Ep) ⊗ R1,3
Recalling the Dirac equation on flat spacetime,
| \mu\partial | |
| (i\gamma | |
| \mu |
-m)\psi=0,
In this way, Dirac's equation takes the following form in curved spacetime:[1]
where
\Psi
(1/2,0) ⊕ (0,1/2).
The modified Klein–Gordon equation obtained by squaring the operator in the Dirac equation, first found by Erwin Schrödinger as cited by Pollock is given by
| \left( | 1 |
| \sqrt{-\detg |
R
F\mu\nu
A\mu
Note that here Latin indices denote the "Lorentzian" vierbein labels while Greek indices denote manifold coordinate indices.
We can formulate this theory in terms of an action. If in addition the spacetime
(M,g)
\epsilon
\intM\epsilonf=\intMd4x\sqrt{-g}f
\bar\Psi(i\gamma\muD\mu-m)\Psi