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Quantum Algorithms
Retarded resonance Casimir-Polder interaction of a uniformly rotating two-atom system
arXiv
Authors: Saptarshi Saha, Chiranjeeb Singha, Arpan Chatterjee
Year
2020
Paper ID
21107
Status
Preprint
Abstract Read
~2 min
Abstract Words
168
Citations
N/A
Abstract
We consider here, a two-atom system is uniformly moving through a circular ring at an ultra-relativistic speed and weakly interacting with common external fields. The vacuum fluctuations of the quantum fields generate the entanglement between the atoms. Hence an effective energy shift is originated, which depends on the inter-atomic distance. This is commonly known as resonance Casimir-Polder interaction (RCPI). It is well known that, for a linearly accelerated system coupled with a massless scalar field, we get a thermal response when the local inertial approximation is valid. On the contrary, the non-thermality arises in the presence of the centripetal acceleration. We use the quantum master equation formalism to calculate the second-order energy shift of the entangled states in the presence of two kinds of fields. They are the massive free scalar field and the electromagnetic vector field. For both cases, we observe the non-thermal behavior. A unique retarded response is also noticed in comparison to the free massless case, which can be observed via the polarization transfer technique.
Why This Paper Matters
- It adds a 2020 reference point for readers tracking recent quantum research.
- We consider here, a two-atom system is uniformly moving through a circular ring at an ultra-relativistic speed and weakly interacting with common external fields.
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