On the Inaccessibility of Time Machines
Abstract
:1. Introduction
2. Basic Structure of Time Machine Spacetimes
3. Holography of Time Machines
3.1. Two-Dimensional Time Machines
3.2. n-Dimensional Time Machines
3.3. Adding Backreaction
4. Time in Traversable Wormholes
- Acquire a traversable wormhole;
- Induce a growing time-shift between the wormhole mouths;
- Wait long enough.
Heuristic Argument Using the AANEC
5. Discussion
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
1 | In the same paper, the AANEC was used to forbid the realization of short traversable wormholes; all the known examples mentioned above are wormholes whose length is longer than the ambient space distance between the mouths. |
2 | One might worry that putting a CFT on a pathological spacetime might nullify the holographic map; after all, are pathologies on the boundary not mapped to pathologies in the bulk? This worry might be justified if our whole boundary spacetime was filled with CTCs (in other words, an eternal time machine). However, we will see that our models start with a completely regular spacetime which, at some point, develops a chronology horizon. This way, our initial value problem is well-defined, and one can proceed with the bulk reconstruction. |
3 | The exact transformation is found in [20]. |
4 | This is not true for Kerr inner horizons, as discussed in Section 5. |
5 | They also find the rotating BTZ solution on the boundary, but this will not be of interest to us here. |
6 | Note that the counterterms vary with respect to the number of spacetime dimensions. |
7 | For more details, see [39]. |
8 | We emphasize that the experimental confirmation of their existence is still lacking. |
9 | In [18], this step is replaced by “bring the mouths close together”. This version assumes that the second step simply induces a time-shift that changes the synchronization between the mouth clocks. As such, if the time-shift does not grow large enough, no time machine could have been created without making the ambient distance shorter than the time-shifted wormhole length. |
10 | |
11 | Disregarding backreaction. |
12 | If there are gravitational redshifts within the wormhole, then we simply need to know how the internal time hooks up to the exterior time at the two mouths. |
13 | The calculation done in [42] is believed to be correct also for the Kerr black hole, although a proper calculation has not been done yet. One could have thought that we could use our knowledge about Misner–AdS spacetimes to infer that the Kerr inner horizon is similarly singular. Namely, if in the near inner horizon limit of the Kerr black hole, one finds the solution of the kind Misner–AdS, where X is some compact manifold, then our problem would be solved—Misner–AdS leads to a divergent stress tensor at the chronology horizon, which would confirm the strong cosmic censorship. However, this is not the case: as one takes the limit close to the inner horizon, one finds a Rindler geometry instead. This is to say that the chronology horizon is a completely regular surface; Misner–AdS gives a quasi-regular surface only [21]. Nevertheless, as argued in [35], we expect higher-order quantum corrections to destabilize even these regular surfaces. |
14 | In progress [43]. |
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Tomašević, M. On the Inaccessibility of Time Machines. Universe 2023, 9, 159. https://doi.org/10.3390/universe9040159
Tomašević M. On the Inaccessibility of Time Machines. Universe. 2023; 9(4):159. https://doi.org/10.3390/universe9040159
Chicago/Turabian StyleTomašević, Marija. 2023. "On the Inaccessibility of Time Machines" Universe 9, no. 4: 159. https://doi.org/10.3390/universe9040159
APA StyleTomašević, M. (2023). On the Inaccessibility of Time Machines. Universe, 9(4), 159. https://doi.org/10.3390/universe9040159