# Creating a wormhole connecting two universes with different spacetime metrics?

A civilization wishes to create a wormhole connecting its universe to a universe with a different spacetime metric. For instance if we describe a timelike dimension with $$+$$ symbol and a spacelike dimension with $$-$$ symbol then this wormhole could connect a universe with the spacetime metric $$(---+)$$ to a universe with the spacetime metric $$(++++)$$. Alternatively if the civilization was in a universe with the spacetime metric $$(++++)$$ the wormhole might connect to a universe with a spacetime metric $$(+++++)$$.

Would such a wormhole be possible assuming that wormholes are possible? If such a wormhole is possible how would the geometry right at the border between the two universes with different spacetime metrics work? Would it be possible to send macroscopic objects through such a wormhole or only elementary particles?

• That's great. Still not sure how we deal with a universe with only timelike metrics and no space. Additional reading: space.mit.edu/home/tegmark/dimensions.html There might be someone on the Physics stack who can give you an answer, you might get lucky here if one of them has the (+) to drop in. Apr 25, 2019 at 4:01
• Hard-science and reality check contrast each other. Please pick one
– L.Dutch
Apr 25, 2019 at 5:05
• @Agrajag Good suggestion. I suspect the OP's concept of timelike and spacelike dimensions doesn't correspond to conventional notions of dimensions of space and time. This is confusing & makes it difficult to understand the nature of the proposed metrics. The possible answers to the question may be perhaps or who knows. Apr 25, 2019 at 6:09
• Within general relativity at least, I think this is impossible. The metric tensor of a pseudo-Riemannian manifold is everywhere nondegenerate, but for it to change signature from one spacetime point to another it would have to pass through the subspace of singular metrics somewhere along the path connecting them (in other words, to go from $+$ to $-$ smoothly one has to pass through $0$, and a signature with $0$s is not allowed in ordinary GR). Apr 25, 2019 at 7:13
• @pregunton This would be a perfectly viable answer. Please consider converting your comment into a proper answer. Quoting a source that states that "a signature with 0s is not allowed in ordinary GR" should be enough to satisfy the hard science requirements.
– Elmy
Apr 25, 2019 at 7:52

Within general relativity at least, I think this is impossible. The metric tensor of a pseudo-Riemannian manifold is usually taken to be everywhere nondegenerate (see e.g. this source. A metric is nondegenerate when its determinant is nonzero, or equivalently when it has no $$0$$ eigenvalues), but for it to change signature from one spacetime point to another it would have to pass through the subspace of singular metrics somewhere along the path connecting them.
In other words, to go from $$+$$ to $$-$$ smoothly one has to pass through $$0$$, and a signature with $$0$$s is not allowed in ordinary GR.
• Allow for degenerate metrics: this case entails important limitations on what you can do. For example, you can't even define Christoffel symbols since they involve the inverse of the metric, and $$1/0$$ is not defined.
• Allow for complex numbers: here you can go from $$+$$ to $$-$$ and bypass $$0$$ by going around it in the complex plane. In fact, all nondegenerate signatures become equivalent in this setting. I know this is used sometimes in quantum field theory as a calculational "trick" called Wick rotation, but I am not aware of any accepted physical meaning of complex coordinates, aside from Hawking's famous cosmological proposal involving imaginary time.