Decoherence Time Induced by The Noise of Primordial Graviton With
Minimum Uncertainty Initial States
- URL: http://arxiv.org/abs/2305.06534v3
- Date: Mon, 22 Jan 2024 15:36:17 GMT
- Title: Decoherence Time Induced by The Noise of Primordial Graviton With
Minimum Uncertainty Initial States
- Authors: Anom Trenggana, Freddy P. Zen, and Getbogi Hikmawan
- Abstract summary: We investigated the decoherence time induced by primordial gravitons with minimum uncertainty initial states.
For initial state entanglement, the decoherence time will last a maximum of 20 seconds, similar to the initial Bunch-Davies vacuum.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: We have investigated the decoherence time induced by the primordial gravitons
with minimum uncertainty initial states. This minimum uncertainty condition
allows the initial state to be an entanglement or, more generally, a
superposition between a vacuum and an entanglement state. We got that for
initial state entanglement, the decoherence time will last a maximum of 20
seconds, similar to the initial Bunch-Davies vacuum, and if the total graviton
is greater than zero, the dimensions of the experimental setup system could be
reduced. We also found that quantum noise can last much longer than vacuum or
entanglement states for initial state superposition, which will be maintained
for $\approx 10^{19}$ seconds.
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