Detecting a Long-Lived False Vacuum with Quantum Quenches
-
1.
National Research Council
-
2.
California Institute of Technology
-
3.
Massachusetts Institute of Technology
Abstract
Distinguishing whether a system supports alternate low-energy (locally stable) states—stable (true vacuum) versus metastable (false vacuum)—by direct observation can be difficult when the lifetime of the state is very long but otherwise unknown. Here we demonstrate, in a tractable model system, that there are physical phenomena on much shorter timescales that can diagnose the difference. Specifically, we study the time evolution of the magnetization following a quench in the tilted quantum Ising model, and show that its magnitude spectrum is an effective diagnostic. Small transition bubbles are more common than large ones, and we see characteristic differences in the size dependence of bubble lifetimes even well below the critical size for false vacuum decay. We expect this sort of behavior to be generic in systems of this kind. We show such signatures persist in a continuum field theory. This also opens the possibility of similar signatures of the potential metastable false vacuum of our universe well before the beginning of a decay process to the true vacuum.
Copyright and License
© 2024 American Physical Society.
Acknowledgement
We acknowledge useful discussions with A. Bastianello, P. Calabrese, S. B. Rutkevich, and G. Takács. F. M. S. acknowledges support provided by the U.S. Department of Energy Office of Science, Office of Advanced Scientific Computing Research, (DE-SC0020290), by Amazon Web Services, AWS Quantum Program, and by the DOE QuantISED program through the theory consortium “Intersections of QIS and Theoretical Particle Physics” at Fermilab. F. W. is supported by the U.S. Department of Energy under grant Contract No. DE-SC0012567, by the European Research Council under Grant No. 742104, and by the Swedish Research Council under Contract No. 335-2014-7424. G. L. would like to express his gratitude to Niccolò Maffezzoli from Ca’ Foscari University of Venice for his support and continuous encouragement. G. L. acknowledge the support by the P1-0044 program of the Slovenian Research Agency, the QuatERA grants QuSiED and T-NiSQ by MVZI, QuantERA II JTC 2021, and ERC StG 2022 project DrumS, Grant Agreement No. 101077265.
Supplemental Material
Supplemental Material (PDF): we discuss in detail the derivation of the results shown in the main text.
Files
| Name | Size | Download all |
|---|---|---|
|
md5:c448fd2d5d312d0bb66b3c41a28dbe26
|
1.3 MB | Preview Download |
|
md5:a956171d48233805667b1fda1b9a5428
|
801.7 kB | Preview Download |
Additional details
- United States Department of Energy
- DE-SC0020290
- Amazon (United States)
- United States Department of Energy
- DE-SC0012567
- European Research Council
- 742104
- Swedish Research Council
- 335-2014-7424
- The Slovenian Research and Innovation Agency
- European Research Council
- 101077265
- Accepted
-
2024-10-24Accepted
- Caltech groups
- AWS Center for Quantum Computing, Institute for Quantum Information and Matter
- Publication Status
- Published