Flyover vacuum decay

We use analytic estimates and numerical simulations to explore the stochastic approach to vacuum decay. According to this approach, the time derivative of a scalar field, which is in a local vacuum state, develops a large fluctuation and the field “flies over” a potential barrier to another vacuum. The probability distribution for the initial fluctuation is found quantum mechanically, while the subsequent nonlinear evolution is determined by classical dynamics. We find in a variety of cases that the rate of such flyover transitions has the same parametric form as that of tunneling transitions calculated using the instanton method, differing only by a numerical factor O(1) in the exponent. An important exception is an “upward” transition from a de Sitter vacuum to a higher-energy de Sitter vacuum state. The rate of flyover transitions in this case is parametrically different and can be many orders of magnitude higher than tunneling. This result is in conflict with the conventional picture of quantum de Sitter space as a thermal state. Our numerical simulations indicate that the dynamics of bubble nucleation in flyover transitions is rather different from the standard picture. The difference is especially strong for thin-wall bubbles in flat space, where the transition region oscillates between true and false vacuum until a true vacuum shell is formed which expands both inwards and outwards, and for upward de Sitter transitions, where the inflating new vacuum region is contained inside of a black hole.

[1]  M. Spannowsky,et al.  Quantum-Field-Theoretic Simulation Platform for Observing the Fate of the False Vacuum , 2021 .

[2]  M. Hertzberg,et al.  Vacuum decay in real time and imaginary time formalisms , 2019, Physical Review D.

[3]  H. Peiris,et al.  New Semiclassical Picture of Vacuum Decay. , 2018, Physical review letters.

[4]  W. Hager,et al.  and s , 2019, Shallow Water Hydraulics.

[5]  R. Sarpong,et al.  Bio-inspired synthesis of xishacorenes A, B, and C, and a new congener from fuscol† †Electronic supplementary information (ESI) available. See DOI: 10.1039/c9sc02572c , 2019, Chemical science.

[6]  A. Vilenkin,et al.  Primordial black hole formation by vacuum bubbles , 2017, 1710.02865.

[7]  Vacuum radiation pressure fluctuations and barrier penetration , 2016, 1610.01252.

[8]  A. Vilenkin,et al.  Black holes and the multiverse , 2015, 1512.01819.

[9]  M. Dine,et al.  Tunneling in theories with many fields , 2015, 1506.06428.

[10]  Adam R. Brown,et al.  Populating the whole landscape. , 2011, Physical review letters.

[11]  A. Guth,et al.  Eternal inflation, bubble collisions and the persistence of memory , 2006, hep-th/0612242.

[12]  A. Aguirre,et al.  Two tunnels to inflation , 2005, gr-qc/0512034.

[13]  A. Mégevand,et al.  Decay of de Sitter Vacua by Thermal Activation , 2004, hep-th/0404097.

[14]  L. Susskind,et al.  Disturbing Implications of a Cosmological Constant , 2002, hep-th/0208013.

[15]  A. Roura,et al.  Dissipation, noise, and vacuum decay in quantum field theory. , 2001, Physical review letters.

[16]  A. Roura,et al.  Vacuum decay in quantum field theory , 2001, hep-ph/0106091.

[17]  A. Guth Eternal Inflation , 2001, Annals of the New York Academy of Sciences.

[18]  U. Sarid Tools for tunneling from metastable vacua , 1998, hep-ph/9804308.

[19]  Andrei Linde Stochastic approach to tunneling and baby universe formation , 1992 .

[20]  Andrei Linde Hard Art of the Universe Creation , 1991, hep-th/9110037.

[21]  Basu,et al.  Quantum creation of topological defects during inflation. , 1991, Physical review. D, Particles and fields.

[22]  J. Ellis,et al.  Vacuum stability, wormholes, cosmic rays and the cosmological bounds on mt and mH , 1990 .

[23]  E. Farhi,et al.  Is it possible to create a universe in the laboratory by quantum tunneling , 1990 .

[24]  R. Konoplich Decay of the false vacuum at finite temperature , 1989 .

[25]  Lee,et al.  Decay of the true vacuum in curved space-time. , 1987, Physical review. D, Particles and fields.

[26]  Andrei Linde Decay of the false vacuum at finite temperature , 1983 .

[27]  S. Hawking,et al.  Supercooled Phase Transitions in the Very Early Universe , 1982 .

[28]  S. Coleman,et al.  Gravitational Effects on and of Vacuum Decay , 1980 .

[29]  S. Coleman The Fate of the False Vacuum. 1. Semiclassical Theory , 1977 .

[30]  G. S. Martin Dissipation , 1904, The American journal of dental science.

[31]  Martí I Franqués Eternal inflation , bubble collisions , and the persistence of memory , 2022 .