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=== Wormholes and faster-than-light space travel === | === Wormholes and faster-than-light space travel === | ||
Often there is confusion about the idea that wormholes allow superluminal (]) space travel. In fact there is no real superluminal travel involved. Assume that the wormhole connects two remote locations. While traveling through a wormhole, subluminal (slower-than-light) speeds can be used. The time in which the distance was traveled would appear faster than it would take light to make the journey through normal space. | Often there is confusion about the idea that wormholes allow superluminal (]) space travel. In fact there is no real superluminal travel involved. Assume that the wormhole connects two remote locations. While traveling through a wormhole, subluminal (slower-than-light) speeds can be used. The time in which the distance was traveled would appear faster(due to the fact that it goes thru a line(a-b) in a ] instead of going thru space outside of the wormhole, which is like going thru the center of an apple rather than going around it on the outside, hence the name ]) than it would take light to make the journey through normal space. | ||
=== Wormholes and time travel === | === Wormholes and time travel === |
Revision as of 00:32, 21 May 2006
For other uses, see Wormhole (disambiguation).In physics, a wormhole is a hypothetical topological feature of spacetime that is essentially a "shortcut" through space and time. A wormhole has at least two mouths which are connected to a single throat. If the wormhole is traversable, matter can 'travel' from one mouth to the other by passing through the throat.
The name "wormhole" comes from an analogy used to explain the phenomenon. If a worm is travelling over the skin of an apple, then the worm could take a shortcut to the opposite side of the apple's skin by burrowing through its center, rather than travelling the entire distance around, just as a wormhole traveller could take a shortcut to the opposite side of the universe through a hole in higher-dimensional space.
Definition
There is a compact region of spacetime whose boundary is topologically trivial but whose interior is not simply connected. Formalizing this idea leads to definitions such as the following, taken from Matt Visser's Lorentzian Wormholes:
- If a Lorentzian spacetime contains a compact region Ω, and if the topology of Ω is of the form Ω ~ R x Σ, where Σ is a three-manifold of nontrivial topology, whose boundary has topology of the form dΣ ~ S², and if furthermore the hypersurfaces Σ are all spacelike, then the region Ω contains a quasipermanent intra-universe wormhole.
Characterizing inter-universe wormholes is more difficult. For example, one can imagine a 'baby' universe connected to its 'parent' by a narrow 'umbilicus'. One might like to regard the umbilicus as the throat of a wormhole, but the spacetime is simply connected.
Wormhole types
Intra-universe wormholes connect one location of a universe to another location of the same universe(in the same present time). A wormhole should be able to connect distant locations in the universe by bending spacetime, allowing travel between them that is faster than it would take light to make the journey through normal space. See the image above. Inter-universe wormholes connect one universe with another , . This gives rise to the speculation that such wormholes could be used to travel from one parallel universe to another. A wormhole which connects (usually closed) universes is often called a Schwarzschild wormhole. Another application of a wormhole might be time travel. In that case it is a shortcut from one point in space and time to another. In string theory a wormhole has been envisioned to connect two D-branes, where the mouths are attached to the branes and are connected by a flux tube . Finally, wormholes are believed to be a part of spacetime foam . There are two main types of wormholes: Lorentzian wormholes and Euclidean wormholes. Lorentzian wormholes are mainly studied in semiclassical gravity and Euclidean wormholes are studied in particle physics. Traversable wormholes are a special kind of Lorentzian wormholes which would allow a human to travel from one side of the wormhole to the other. Sergey Krasnikov tossed the term spacetime shortcut as a more general term for (traversable) wormholes and propulsion systems like the Alcubierre drive and the Krasnikov tube to indicate hyperfast interstellar travel.
Theoretical basis
It is unknown whether (Lorentzian) wormholes are possible or not within the framework of general relativity. Most known solutions of general relativity which allow for wormholes require the existence of exotic matter, a theoretical substance which has negative energy density. However, it has not been mathematically proven that this is an absolute requirement for wormholes, nor has it been established that exotic matter cannot exist. Recently Amos Ori envisioned a wormhole which allowed time travel, did not require any exotic matter, and satisfied the weak, dominant, and strong energy conditions . Since there is no established theory of quantum gravity, it is impossible to say with any certainty whether wormholes are possible or not within that theoretical framework.
Traversable wormholes
Lorentzian traversable wormholes would allow travel from one part of the universe to another part of that same universe very quickly or would allow travel from one universe to another universe. Wormholes connect two points in spacetime, which means that they would allow travel in time as well as in space.
Wormholes and faster-than-light space travel
Often there is confusion about the idea that wormholes allow superluminal (faster-than-light) space travel. In fact there is no real superluminal travel involved. Assume that the wormhole connects two remote locations. While traveling through a wormhole, subluminal (slower-than-light) speeds can be used. The time in which the distance was traveled would appear faster(due to the fact that it goes thru a line(a-b) in a curved space instead of going thru space outside of the wormhole, which is like going thru the center of an apple rather than going around it on the outside, hence the name wormhole) than it would take light to make the journey through normal space.
Wormholes and time travel
A wormhole could allow time travel. This could be accomplished by accelerating one end of the wormhole relative to the other, and then sometime later bringing it back; relativistic time dilation would result in less time having passed for the accelerated wormhole mouth compared with the stationary one, meaning that anything which entered the stationary wormhole mouth would exit the accelerated one at a point in time prior to its entry. The path through such a wormhole is called a closed timelike curve, and a wormhole with this property is sometimes referred to as a "timehole."
It is thought that it may not be possible to convert a wormhole into a time machine in this manner, however; some mathematical models indicate that a feedback loop of virtual particles would circulate through the timehole with ever-increasing intensity, destroying it before any information could be passed through it. This has been called into question by the suggestion that radiation would disperse after traveling through the wormhole, therefore preventing infinite accumulation. There is also the Roman ring, which is a very stable configuration of more than one wormhole. This ring allows a closed time loop with stable wormholes. The debate on this matter is described by Kip S. Thorne in the book Black Holes and Time Warps , and will likely require a theory of quantum gravity to resolve.
Many physicists, including Stephen Hawking (see Hawking's Chronology Protection Conjecture), believe that due to the problems a wormhole would theoretically create, including allowing time travel, that something fundamental in the laws of physics would prohibit them. However, this remains speculation, and the notion that nature would censor inconvenient objects has already failed in the case of the cosmic censorship hypothesis.
Schwarzschild wormholes
Wormholes known as Schwarzschild wormholes or Einstein-Rosen bridges are bridges between areas of space that can be modelled as vacuum solutions to the Einstein field equations by sticking a model of a black hole and a model of a white hole together. However, this type of wormhole is unstable enough to pinch off instantly as soon as it forms.
While the equations of General Relativity suggest that a Schwarzschild wormhole could be stabilized by holding its "throat" open with material that has negative mass, it would still be impossible for a traveller to go through this type of wormhole because they can only go through an event horizon in one direction, and both ends of the hole have an event horizon. This leaves the traveller trapped in the middle of the wormhole.
Before the stability problems of Schwarzschild wormholes were apparent, it was proposed that quasars were white holes forming the ends of wormholes of this type.
Wormhole Metrics
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Theories of wormhole metrics describe the spacetime geometry of a wormhole and serve as theoretical models for time travel. A simple example of a (traversable) wormhole metric is the following:
One type of non-traversable wormhole metric is the schwarzschild solution:
Wormholes in fiction
Wormholes are also a popular feature of science fiction as they allow interstellar travel within human timescales.
They are a centerpiece of Carl Sagan's novel Contact, for which Kip Thorne advised Sagan on the possibilities of wormholes.
The setting of the television series Star Trek: Deep Space Nine is a space station, Deep Space Nine, located near the Bajoran wormhole. This wormhole is unique in the Star Trek universe because of its stability. It provides passage to the distant Gamma Quadrant, opening a gate to starships that extends far beyond the reach normally attainable. It is also the source of a severe threat to the Alpha Quadrant from an empire called the Dominion.
Wormholes are also the principal means of space travel in the Stargate movie and the spin-off television series, Stargate SG-1 and Stargate Atlantis. The central plot device of the programs is a transportation network consisting of the ring-shaped devices known as Stargates, which generate wormholes that allow one-way matter transmission and two-way EM radiation transmission (allowing two way communication) between gates when the correct spatial coordinates are "dialed". However, for some reason not fully explained the water-like event horizon breaks down the matter into energy for transport through the wormhole, organising it into its original state at the destination. This is presumably because in the Stargate movie and shows, only other forms of energy can travel through the wormholes, which would also be why EM energy can travel both ways: it doesn't have to be converted. For Additonal Information see: Stargate (device), and Wormhole physics (Stargate)
In 2005 wormholes were used to support the plot of the television miniseries The Triangle.
The television series Farscape features an American astronaut who accidentally gets shot through a wormhole and ends up in a distant part of the universe, and also features the use of wormholes to reach other universes (or "unrealized realities") and as weapons of mass destruction.
In the FOX/Sci-Fi series Sliders, a method is found to create a wormhole that allows travel not between distant points but between different universes; objects or people that travel through the wormhole begin and end in the same location geographically (e.g. if one leaves San Francisco, one will arrive in an alternate San Francisco) and chronologically (if it is 1999 at the origin point, so it is at the destination, at least by the currently-accepted calendar on our Earth.) Early in the series the wormhole is referred to by the name Einstein-Rosen-Podolsky bridge. This series presumes that we exist as part of a multiverse and asks what might have resulted had major or minor events in history occurred differently; it is these choices that give rise to the alternate universes in which the series is set. The same premise is used in the Star Trek: The Next Generation episode Parallels and the Star Trek: The Original Series episode The Alternative Factor which premiered in 1967.
In Star Trek: The Motion Picture, Willard Decker recalls that "Voyager 6" (aka V'ger) disappeared into what they used to call a "black hole". At one time, black holes in science fiction were often incorrectly endowed with the traits of wormholes. This has for the most part disappeared as a black hole isn't really a hole in space but a dense mass and the visible vortex effect often associated with black holes is merely the accretion disk of visible matter being drawn toward it. Decker's line is most likely to inform that it was probably a wormhole that Voyager 6 entered.
In 2000, Arthur C. Clarke and Stephen Baxter co-wrote a science fiction novel, The Light of Other Days, which discusses the problems which arise when a wormhole is used for faster than light communication.
A related method of faster-than-light travel that often arises in science fiction, especially military science fiction, is a "jump drive" that can propel a spacecraft between two fixed "jump points" connecting solar systems. Connecting solar systems in a network like this results in a fixed "terrain" with choke points that can be useful for constructing plots related to military campaigns. The Alderson points postulated by Larry Niven and Jerry Pournelle in Mote in God's Eye and related novels is an especially well thought out example. The development process is described by Niven in N-Space, a volume of collected works. David Weber has also used the device in the Honorverse and other books such as those based upon the Starfire universe, and has described a 'history' of development and exploitation in several essays in collections of related short stories.
The Commonwealth Saga by Peter F. Hamilton describes how wormhole technology could be used to explore, colonize and connect to other worlds without having to resort to traditional travel via starships. This technology is the basis of the formation of the titular Intersolar Commonwealth, and is used so extensively that it is possible to ride trains between the planets of the Commonwealth.
Richard Kelly's science-fiction movie, Donnie Darko, also explores the possibility of the existence of wormholes in the universe. While in the original theatrical release, the relevance of wormholes to the plot is unclear, in the Director's Cut, the 'book' "The Philosophy of Time Travel" is presented in more depth. In this version, the wormhole is the path connecting the real universe, and the parallel universe, which in the movie lasts from the jet engine crashing into the Darko family home until Halloween when the actual jet loses its engine to the wormhole, at which point the parallel universe collapses.
Lois McMaster Bujold uses wormholes as a major transportation system in the Miles Vorkosigan novels. Control over wormhole routes and jumps even become the basis for war.
In the sci-fi horror film Event Horizon, an advanced spaceship designed for faster-than-light travel uses a projected beam of gravitons to artificially create a wormhole, allowing the ship to traverse large distances instantaneously. The maiden flight does not go as planned, and the ship travels to a place outside the known universe (seemingly a version of Hell), consequently bringing back the horrors of the visited place.
In the novel Halo: First Strike, the AI Cortana (as a narrator of a situation) mentions that a wormhole is the way to reach the higher dimension called "Slipspace."
"Strange Days at Blake Holsey High", a television series running from 2002-2006, focuses on the havoc caused by a wormhole present in the school itself. This wormhole was a by-product of experiments taking place in Pearadyne Laboratories, a company owned by Victor Pearson and actually located under the school. Strange things happen all the time at Blake Holsey High, and it is up to the science club to solve the mystery surrounding Pearadyne.
In the on-line fictional collaborative worldbuilding project "Orion's Arm" wormholes are used for communication between the millions of colonies in the local part of the Milky way Galaxy. In an attempt to make the physics of the wormhole travel at least semi-plausible, large amounts of ANEC violating exotic energy are required to maintain the holes, which are never-the-less large objects which must be maintained on the outermost reaches of the planetary systems concerned.
In "Power Rangers Time Force, artifical Temporal Wormholes were used extensivly for the delivery of the Time Fliers to travel to the past to aid the Rangers and was also used by Wes, Eric and Commandocon to travel to prehistoric times to recover the Quantasaurus Rex.
In "Power Rangers SPD, in the Episode Wormhole, Gruumm and later the SPD Rangers used a "Temporal Wormole" to travel from 2020 to 2004 to battle with the Dino Thunder Rangers in early 21st century Reefside.
See also
- Black hole
- Rotating black hole
- White hole
- Gravastar
- Compact stars
- Faster-than-light
- Chronology protection conjecture
- Alcubierre drive
- Neutron star
- Self-consistency principle
- Roman ring
- Schwarzschild metric
- Schwarzschild radius
- String theory
- Theory of relativity
- Time travel
- Timeline of black hole physics
- Spacecraft propulsion
- Bajoran wormhole
- Stargate
References
- Visser, Matt. "The quantum physics of chronology protection by Matt Visser". arXiv eprint server. Retrieved August 12.
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suggested) (help) An excellent and more concise review. - Khatsymosky, Vladimir M. "Towards possibility of self-maintained vacuum traversable wormhole". arXiv eprint server. Retrieved August 12.
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suggested) (help) - Roman, Thomas, A. "Some Thoughts on Energy Conditions and Wormholes". arXiv eprint server. Retrieved August 12.
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suggested) (help)CS1 maint: multiple names: authors list (link) - Krasnikov, Serguei. "The quantum inequalities do not forbid spacetime shortcuts". arXiv eprint server. Retrieved August 12.
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suggested) (help) - Krasnikov, Serguei. "Counter example to a quantum inequality". arXiv eprint server. Retrieved August 12.
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suggested) (help) - Teo, Edward. "Rotating traversable wormholes". arXiv eprint server. Retrieved August 12.
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ignored (|access-date=
suggested) (help) - González-Díaz, Pedro F. "Ringholes and closed timelike curves". arXiv eprint server. Retrieved August 12.
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ignored (|access-date=
suggested) (help) - González-Díaz, Pedro F. "Quantum time machine". arXiv eprint server. Retrieved August 12.
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ignored (|access-date=
suggested) (help) - DeBenedictis, Andrew and Das, A. "On a General Class of Wormhole Geometries". arXiv eprint server. Retrieved August 12.
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suggested) (help)CS1 maint: multiple names: authors list (link) - Li, Li-Xin. "Two Open Universes Connected by a Wormhole: Exact Solutions". arXiv eprint server. Retrieved August 12.
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ignored (|access-date=
suggested) (help) - Nandi, Kamal K. and Zhang, Yuan-Zhong. "A Quantum Constraint for the Physical Viability of Classical Traversable Lorentzian Wormholes". arXiv eprint server. Retrieved August 12.
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suggested) (help)CS1 maint: multiple names: authors list (link) - Dzhunushaliev, Vladimir. "Strings in the Einstein's paradigm of matter". arXiv eprint server. Retrieved August 12.
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suggested) (help) - Garattini, Remo. "How Spacetime Foam modifies the brick wall". arXiv eprint server. Retrieved August 12.
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External links
- What exactly is a 'wormhole'? answered by Richard F. Holman, William A. Hiscock and Matt Visser.
- Why wormholes? by Matt Visser.
- Wormholes in General Relativity by Soshichi Uchii.
- Time, Time Travel & Traversable Wormholes includes a discussion forum.
- White holes and Wormholes provides a very good description of Schwarzschild wormholes with graphics and animations, by Andrew J. S. Hamilton.
- Wormhole on arxiv.org