Discrete Poisson equation

In general relativity, optical scalars refer to a set of three scalar functions ${\displaystyle \{\hat{\theta }}$ (expansion), ${\displaystyle \hat{\sigma }}$ (shear) and ${\displaystyle \hat{\omega }}$ (twist/rotation/vorticity)${\displaystyle \}}$ describing the propagation of a geodesic null congruence.^{[1][2][3][4][5]}

In fact, these three scalars ${\displaystyle \{\hat{\theta },\hat{\sigma },\hat{\omega }\}}$ can be defined for both timelike and null geodesic congruences in an identical spirit, but they are called "optical scalars" only for the null case. Also, it is their tensorial predecessors ${\displaystyle \{\hat{\theta }{\hat{h}}_{ab},{\hat{\sigma }}_{ab},{\hat{\omega }}_{ab}\}}$ that are adopted in tensorial equations, while the scalars ${\displaystyle \{\hat{\theta },\hat{\sigma },\hat{\omega }\}}$ mainly show up in equations written in the language of Newman-Penrose formalism.

Definitions: expansion, shear and twist

For geodesic timelike congruences

Denote the tangent vector field of an observer's worldline (in a timelike congruence) as ${\displaystyle Z^a}$, and then one could construct induced "spatial metrics" that

${\displaystyle (1)h^{ab}=g^{ab}+Z^a{Z}^b,h_{ab}=g_{ab}+Z_a{Z}_b,h_b^a=g_b^a+Z^a{Z}_b,}$

where ${\displaystyle h_b^a}$ works as a spatially projecting operator. Use ${\displaystyle h_b^a}$ to project the coordinate covariant derivative ${\displaystyle {\mathrm{\nabla }}_b{Z}_a}$ and one obtains the "spatial" auxiliary tensor ${\displaystyle B_{ab}}$,

${\displaystyle (2)B_{ab}=h_a^c{h}_b^d{\mathrm{\nabla }}_d{Z}_c={\mathrm{\nabla }}_b{Z}_a+A_a{Z}_b,}$

where ${\displaystyle A_a}$ represents the four-acceleration, and ${\displaystyle B_{ab}}$ is purely spatial in the sense that ${\displaystyle B_{ab}{Z}^a=B_{ab}{Z}^b=0}$. Specifically for an observer with a "geodesic" timelike worldline, we have

${\displaystyle (3)A_a=0,\Rightarrow B_{ab}={\mathrm{\nabla }}_b{Z}_a.}$

Now decompose ${\displaystyle B_{ab}}$ into the symmetric part ${\displaystyle {\theta }_{ab}}$ and ${\displaystyle {\omega }_{ab}}$,

${\displaystyle (4){\theta }_{ab}=B_{(ab)},{\omega }_{ab}=B_{[ab]}.}$

${\displaystyle {\omega }_{ab}=B_{[ab]}}$ is trace-free (${\displaystyle g^{ab}{\omega }_{ab}=0}$) while ${\displaystyle {\theta }_{ab}}$ is of nonzero trace, ${\displaystyle g^{ab}{\theta }_{ab}=\theta }$. Thus, the symmetric part ${\displaystyle {\theta }_{ab}}$ can be further rewritten into its trace and trace-free part,

${\displaystyle (5){\theta }_{ab}=\frac{1}{3}\theta h_{ab}+{\sigma }_{ab}.}$

Hence, all in all we have

${\displaystyle (6)B_{ab}=\frac{1}{3}\theta h_{ab}+{\sigma }_{ab}+{\omega }_{ab},\theta =g^{ab}{\theta }_{ab}=g^{ab}{B}_{(ab)},{\sigma }_{ab}={\theta }_{ab}-\frac{1}{3}\theta h_{ab},{\omega }_{ab}=B_{[ab]}.}$

For geodesic null congruences

Now, consider a geodesic null congruence with tangent vector field ${\displaystyle k^a}$. Similar to the timelike situation, we also define

${\displaystyle (7){\hat{B}}_{ab}:={\mathrm{\nabla }}_b{k}_a,}$

which can be decomposed into

${\displaystyle (8){\hat{B}}_{ab}={\hat{\theta }}_{ab}+{\hat{\omega }}_{ab}=\frac{1}{2}\hat{\theta }{\hat{h}}_{ab}+{\hat{\sigma }}_{ab}+{\hat{\omega }}_{ab},}$

where

${\displaystyle (9){\hat{\theta }}_{ab}={\hat{B}}_{(ab)},\hat{\theta }={\hat{h}}^{ab}{\hat{B}}_{ab},{\hat{\sigma }}_{ab}={\hat{B}}_{(ab)}-\frac{1}{2}\hat{\theta }{\hat{h}}_{ab},{\hat{\omega }}_{ab}={\hat{B}}_{[ab]}.}$

Here, "hatted" quantities are utilized to stress that these quantities for null congruences are two-dimensional as opposed to the three-dimensional timelike case. However, if we only discuss null congruences in a paper, the hats can be omitted for simplicity.

Definitions: optical scalars for null congruences

The optical scalars ${\displaystyle \{\hat{\theta },\hat{\sigma },\hat{\omega }\}}$^{[1][2][3][4][5]} come straightforwardly from "scalarization" of the tensors ${\displaystyle \{\hat{\theta },{\hat{\sigma }}_{ab},{\hat{\omega }}_{ab}\}}$ in Eq(9).

The expansion of a geodesic null congruence is defined by (where for clearance we will adopt another standard symbol "${\displaystyle ;}$" to denote the covariant derivative ${\displaystyle {\mathrm{\nabla }}_a}$)

${\displaystyle (10)\hat{\theta }=\frac{1}{2}{k}^a{}_{;a}.}$

The shear of a geodesic null congruence is defined by

${\displaystyle (11){\hat{\sigma }}^2={\hat{\sigma }}_{ab}{\hat{\overline{\sigma }}}^{ab}=\frac{1}{2}{g}^{ca}{g}^{db}{k}_{(a;b)}{k}_{c;d}-(\frac{1}{2}{k}^a{}_{;a}{)}^2=g^{ca}{g}^{db}\frac{1}{2}{k}_{(a;b)}{k}_{c;d}-{\hat{\theta }}^2.}$

The twist of a geodesic null congruence is defined by

${\displaystyle (12){\hat{\omega }}^2=\frac{1}{2}{k}_{[a;b]}{k}^{a;b}=g^{ca}{g}^{db}{k}_{[a;b]}{k}_{c;d}.}$

In practice, a geodesic null congruence is usually defined by either its outgoing (${\displaystyle k^a=l^a}$) or ingoing (${\displaystyle k^a=n^a}$) tangent vector field (which are also its null normals). Thus, we obtain two sets of optical scalars ${\displaystyle \{{\hat{\theta }}_{(\ell )},{\hat{\sigma }}_{(\ell )},{\hat{\omega }}_{(\ell )}\}}$ and ${\displaystyle \{{\hat{\theta }}_{(n)},{\hat{\sigma }}_{(n)},{\hat{\omega }}_{(n)}\}}$, which are defined with respect to ${\displaystyle l^a}$ and ${\displaystyle n^a}$, respectively.

Applications in decomposing the propagation equations

For a geodesic timelike congruence

The propagation (or evolution) of ${\displaystyle B_{ab}}$ for a geodesic timelike congruence along ${\displaystyle Z^c}$ respects the following equation,

${\displaystyle (13)Z^c{\mathrm{\nabla }}_c{B}_{ab}=-B_b^c{B}_{ac}+R_{cbad}{Z}^c{Z}^d.}$

Take the trace of Eq(13) by contracting it with ${\displaystyle g^{ab}}$, and Eq(13) becomes

${\displaystyle (14)Z^c{\mathrm{\nabla }}_c\theta ={\theta }_{,\tau }=-\frac{1}{3}{\theta }^2-{\sigma }_{ab}{\sigma }^{ab}+{\omega }_{ab}{\omega }^{ab}-R_{ab}{Z}^a{Z}^b}$

in terms of the quantities in Eq(6). Moreover, the trace-free, symmetric part of Eq(13) is

${\displaystyle (15)Z^c{\mathrm{\nabla }}_c{\sigma }_{ab}=-\frac{2}{3}\theta {\sigma }_{ab}-{\sigma }_{ac}{\sigma }_b^c-{\omega }_{ac}{\omega }_b^c+\frac{1}{3}{h}_{ab}({\sigma }_{cd}{\sigma }^{cd}-{\omega }_{cd}{\omega }^{cd})+C_{cbad}{Z}^c{Z}^d+\frac{1}{2}{\tilde{R}}_{ab}.}$

Finally, the antisymmetric component of Eq(13) yields

${\displaystyle (16)Z^c{\mathrm{\nabla }}_c{\omega }_{ab}=-\frac{2}{3}\theta {\omega }_{ab}-2{\sigma }_{[b}^c{\omega }_{a]c}.}$

For a geodesic null congruence

A (generic) geodesic null congruence obeys the following propagation equation,

${\displaystyle (16)k^c{\mathrm{\nabla }}_c{\hat{B}}_{ab}=-{\hat{B}}_b^c{\hat{B}}_{ac}+\widehat{R_{cbad}{k}^c{k}^d}.}$

With the definitions summarized in Eq(9), Eq(14) could be rewritten into the following componential equations,

${\displaystyle (17)k^c{\mathrm{\nabla }}_c\hat{\theta }={\hat{\theta }}_{,\lambda }=-\frac{1}{2}{\hat{\theta }}^2-{\hat{\sigma }}_{ab}{\hat{\sigma }}^{ab}+{\hat{\omega }}_{ab}{\hat{\omega }}^{ab}-\widehat{R_{cd}{k}^c{k}^d},}$

${\displaystyle (18)k^c{\mathrm{\nabla }}_c{\hat{\sigma }}_{ab}=-\hat{\theta }{\hat{\sigma }}_{ab}+\widehat{C_{cbad}{k}^c{k}^d},}$

${\displaystyle (19)k^c{\mathrm{\nabla }}_c{\hat{\omega }}_{ab}=-\hat{\theta }{\hat{\omega }}_{ab}.}$

For a restricted geodesic null congruence

For a geodesic null congruence restricted on a null hypersurface, we have

${\displaystyle (20)k^c{\mathrm{\nabla }}_c\theta ={\hat{\theta }}_{,\lambda }=-\frac{1}{2}{\hat{\theta }}^2-{\hat{\sigma }}_{ab}{\hat{\sigma }}^{ab}-\widehat{R_{cd}{k}^c{k}^d}+{\kappa }_{(\ell )}\hat{\theta },}$

${\displaystyle (21)k^c{\mathrm{\nabla }}_c{\hat{\sigma }}_{ab}=-\hat{\theta }{\hat{\sigma }}_{ab}+\widehat{C_{cbad}{k}^c{k}^d}+{\kappa }_{(\ell )}{\hat{\sigma }}_{ab},}$

${\displaystyle (22)k^c{\mathrm{\nabla }}_c{\hat{\omega }}_{ab}=0.}$

Spin coefficients, Raychaudhuri's equation and optical scalars

For a better understanding of the previous section, we will briefly review the meanings of relevant NP spin coefficients in depicting null congruences.^[1] The tensor form of Raychaudhuri's equation^[6] governing null flows reads

${\displaystyle (23){\mathcal{ℒ}}_{\ell }{\theta }_{(\ell )}=-\frac{1}{2}{\theta }_{(\ell )}^2+{\tilde{\kappa }}_{(\ell )}{\theta }_{(\ell )}-{\sigma }_{ab}{\sigma }^{ab}+{\tilde{\omega }}_{ab}{\tilde{\omega }}^{ab}-R_{ab}{l}^a{l}^b,}$

where ${\displaystyle {\tilde{\kappa }}_{(\ell )}}$ is defined such that ${\displaystyle {\tilde{\kappa }}_{(\ell )}{l}^b:=l^a{\mathrm{\nabla }}_a{l}^b}$. The quantities in Raychaudhuri's equation are related with the spin coefficients via

${\displaystyle (24){\theta }_{(\ell )}=-(\rho +\overline{\rho })=-2\text{Re}(\rho ),{\theta }_{(n)}=\mu +\overline{\mu }=2\text{Re}(\mu ),}$

${\displaystyle (25){\sigma }_{ab}=-\sigma {\overline{m}}_a{\overline{m}}_b-\overline{\sigma }{m}_a{m}_b,}$

${\displaystyle (26){\tilde{\omega }}_{ab}=\frac{1}{2}(\rho -\overline{\rho })(m_a{\overline{m}}_b-{\overline{m}}_a{m}_b)=\text{Im}(\rho )\cdot (m_a{\overline{m}}_b-{\overline{m}}_a{m}_b),}$

where Eq(24) follows directly from ${\displaystyle {\hat{h}}^{ab}={\hat{h}}^{ba}=m^b{\overline{m}}^a+{\overline{m}}^b{m}^a}$ and

${\displaystyle (27){\theta }_{(\ell )}={\hat{h}}^{ba}{\mathrm{\nabla }}_a{l}_b=m^b{\overline{m}}^a{\mathrm{\nabla }}_a{l}_b+{\overline{m}}^b{m}^a{\mathrm{\nabla }}_a{l}_b=m^b\overline{\delta }{l}_b+{\overline{m}}^b\delta l_b=-(\rho +\overline{\rho }),}$

${\displaystyle (28){\theta }_{(n)}={\hat{h}}^{ba}{\mathrm{\nabla }}_a{n}_b={\overline{m}}^b{m}^a{\mathrm{\nabla }}_a{n}_b+m^b{\overline{m}}^a{\mathrm{\nabla }}_a{n}_b={\overline{m}}^b\delta n_b+m^b\overline{\delta }{n}_b=\mu +\overline{\mu }.}$

See also

• Raychaudhari equation

• Congruence (general relativity)

References

43 year old Petroleum Engineer Harry from Deep River, usually spends time with hobbies and interests like renting movies, property developers in singapore new condominium and vehicle racing. Constantly enjoys going to destinations like Camino Real de Tierra Adentro.