Entropy said:
It is really hard to speculate about wormhole physics because he know so little about them. Wormholes are really at the level of science-fiction. I would imagine if wormholes do exist that the momentum of an object would have to be conserved somehow. Meaning the direction you enter a wormhole has to be the same when you exit one. Just like when a roller coaster does a loop, the normal force of the rail changes the direction of motion of the car, the wormhole would have to apply a force, and therefore supply energy, to the object passing through it.
Wormholes appear a lot in science fiction, but there are serious physics journal articles about them too.
If you read the above thread you'll see some links to some serious papers, a smattering of some of the more famous serious papers about the topic are
W. G. Morris and K. S. Thorne, American Journal of Physics 56, 395-412 (1988);
W. G. Morris, K. S. Thorne, and U. Yurtsever, Phys. Rev. Letters 61, 1446-9 (1988).
Matt Visser, Physical Review D 39, 3182-4 (1989).
S. V. Krasnikov, "Toward a Transversable Wormhole", LANL preprint
gr-qc/0003093, Proc. of the STAIF-2000 Conference, Albuquerque, NM, February 1-4, 2000.
S. V. Krasnikov, "A Transversable Wormhole", LANL preprint gr-qc/9909016 (September 26, 1999)
Speculation is not needed to describe what happens to the energy and momentum of an object entering a wormhole, at least when the wormhole is assumed to be embedded in an asymptotically flat space-time so that the energy and momentum can be unambiguously determined.
Both the energy and momentum of the entering object _must_ be transferred to the wormhole mouth. The remarks I made about this happening for the mass of the wormhole mouth also apply to the momentum and energy of the mouth.
This is because the energy, momentum, and mass of the wormhole mouth can all be determined from the metric of space-time a long ways away from the mouth. Another way of saying this is that it is the properties of the metric "at infinity" that determine the energy, mass, and charge.
These properties "at infinty" are separated by a space-like interval from the object entering the wormhole mouth. Hence, they simply cannot change when an object enters the mouth - they are "fixed" in the imprint of the metric.
The simplest place to start to understand this is to re-read the quote I posted earlier from John Cramer - who is a physicist as well as being a science fiction author. One can determine the charge in an enclosed surface by Gauss's law. What happens to this intergal when a charge passes through the wormhole mouth? The answer is that it does not change. You can think of the electric field lines as remaining connected, and being "dragged through" the wormhole when the charge passes through it. This gives the entrance mouth an effective charge of +Q, where Q is the charge passing through the wormhole. (The exit mouth gains an effective charge of -Q).
The gravitational situation is a bit more complicated, because gravitational field lines are not well defined in GR. But the same basic logic applies - you have an intergal "at infinity" which is a conserved quantity, and it simply cannot change when a mass passes through a wormhole mouth. This means that the object transfers its energy and momentum to the mouth - in a sense, you can think of an object that travels through the wormhole as "leaving behind" its mass and momentum.
Because this is an interesting point, I will take the liberty of repeating myself by reposting the quote in question.
Remeber that the author is BOTH a physicist AND a science-fiction author.
http://www.npl.washington.edu/AV/altvw69.html
As this scenario emerged from our discussion, the focus of the Workshop turned to the question of how, if such natural wormholes exist, we might search for and find them. And we invented a way.
If a positive electric charge Q passes through a wormhole mouth, the electric lines of force radiating away from the charge must thread through the aperture of the wormhole. The net result is that the entrance wormhole mouth has lines of force radiating away from it, and the exit wormhole mouth has lines of force radiating toward it. In effect, the entrance mouth has now been given a positive electric charge Q, and the exit mouth acquires a corresponding negative charge -Q. Similarly, if a mass M passes through a wormhole mouth, the entrance mouth has its mass increased by M, and the exit mouth has its mass reduced by an amount -M.
In the early universe these mass changes might create a dynamically unstable situation. If one natural wormhole mouth begins to increase in mass, its twin will correspondingly be reduced in mass until it acquires a net negative mass. The mouth with positive mass will attract more mass to it, while its negative-mass twin will gravitationally repel any nearby mass. Thus, this mass imbalance should grow until it eventually it is damped by the growing distance scales from the expansion of the universe.
