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''Terminological note:'' this article concerns a standard concept, but there is apparently ''no standard term'' to denote this concept, so we have attempted to supply one for the benefit of Wikipedia .


MATHEMATICAL DEFINITION


The Einstein field equation is often written, with a so-called ''cosmological constant term'', as
: G^{ab} + \Lambda \, g^{ab} = 8 \pi \, T^{ab}
However, it is more sensible to move the extra term to the right hand side and absorb it into the Stress-energy Tensor , so that the cosmological constant term becomes just another contribution to the stress-energy tensor. When other contributions vanish,
: G^{ab} = -\Lambda \, g^{ab}
we have a lambdavacuum. Equivalently, we can write this, in terms of the Ricci Tensor , in the form
R^{ab} = \left( R/2 - \Lambda ight) \, g^{ab}


PHYSICAL INTERPRETATION


A nonzero cosmological constant term can be interpreted in terms of a nonzero Vacuum Energy . There are two cases:
  • \Lambda > 0: positive vacuum energy density and negative vacuum pressure (isotropic suction), as in De Sitter Space ,

  • \Lambda < 0: negative vacuum energy density and positive vacuum pressure, as in Anti-de Sitter Space .

    • The idea of the vacuum having an energy density might seem outrageous, but this does make sense in quantum field theory. Indeed, nonzero vacuum energies can even be experimentally verified in the Casimir Effect .



EINSTEIN TENSOR


The components of a tensor computed with respect to a Frame Field rather than the ''coordinate basis'' are often called ''physical components'', because these are the components which can (in principle) be measured by an observer. A frame consists of four unit vector fields
: ec{e}_0, \; ec{e}_1, \; ec{e}_2, \; ec{e}_3
Here, the first is a Timelike unit vector field and the others are Spacelike unit vector fields, and ec{e}_0 is everywhere orthogonal to the world lines of a family of observers (not necessarily inertial observers).

Remarkably, in the case of lambdavacuum, ''all'' observers measure the ''same'' energy density and the same (isotropic) pressure. That is, the Einstein tensor takes the form
: G^{\hat{a}\hat{b}} = -\Lambda \, \left \begin{matrix} -1&0&0&0\0&1&0&0\0&0&1&0\0&0&0&1\end{matrix} ight
Saying that this tensor takes the same form for ''all'' observers is the same as saying that the Isotropy Group of a lambdavacuum is SO(1,3), the full Lorentz Group .


EIGENVALUES


The Characteristic Polynomial of the Einstein tensor of a lambdavacuum must have the form
: \chi(\zeta) = \left( \zeta + \Lambda ight)^4
Using Newton's Identities , this condition can be re-expressed in terms of the Trace s of the powers of the Einstein tensor as
: t_2 = t_1^2/4, \; t_3 = t_1^3/16, \; t_4 = t_1^4/64
where
: t_1 = {G^a}_a, \; t_2 = {G^a}_b \, {G^b}_a, \; t_3 = {G^a}_b \, {G^b}_c \, {G^c}_a, \; t_4 = {G^a}_b \, {G^b}_c \, {G^c}_d \, {G^d}_a
are the traces of the powers of the linear operator corresponding to the Einstein tensor, which has second rank.


RELATION WITH EINSTEIN MANIFOLDS


The definition of a lambdavacuum solution makes mathematical sense irrespective of any physical interpretation, and lambdavacuums are in fact a special case of a concept which is studied by pure mathematicians.

Einstein Manifold s are Riemannian Manifold s in which the Ricci Tensor is proportional (by some constant, not otherwise specified) to the Metric Tensor . Such manifolds may have the wrong Signature to admit a spacetime interpretation in general relativity, and may have the wrong dimension as well. But the Lorentzian manifolds which are also Einstein manifolds are precisely the Lambdavacuum Solution s.


EXAMPLES


Noteworthy individual examples of lambdavacuum solutions include:


SEE ALSO