dorsal/arxiv
View SchemaTwo - Level Atom - Field Interaction: Exact Master Equations for Non-Markovian Dynamics, Decoherence and Relaxation
| Authors | Charis Anastopoulos, B. L. Hu |
|---|---|
| Categories | |
| ArXiv ID | quant-ph/9901078 |
| URL | https://arxiv.org/abs/quant-ph/9901078 |
| DOI | 10.1103/PhysRevA.62.033821 |
| Journal | Phys.Rev.A62:033821,2000 |
Abstract
We perform a first- principles derivation of the general master equation to study the non-Markovian dynamics of a two-level atom (2LA) interacting with an electromagnetic field (EMF). We use the influence functional method which can incorporate the full backreaction of the field on the atom, while adopting Grassmannian variables for the 2LA and the coherent state representation for the EMF. We find exact master equations for the cases of a free quantum field and a cavity field in the vacuum. In response to the search for mechanisms to preserve maximal coherence in quantum computations in ion trap prototypes, we apply these equations to analyse the decoherence of a 2LA in an EMF, and fine that decoherence time is close to relaxation time. This is at variance to the claims by authors who studied the same system but used a different coupling model. We explain the source of difference and argue that, contrary to common belief, the EMF when resonantly coupled to an atom does not decohere it as efficiently as a bath does on a quantum Brownian particle. The master-equations for non-Markovian dynamics derived here is expected to be useful for exploring new regimes of 2LA-EMF interaction, which is becoming physically important experimentally.
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"abstract": "We perform a first- principles derivation of the general master equation to\nstudy the non-Markovian dynamics of a two-level atom (2LA) interacting with an\nelectromagnetic field (EMF). We use the influence functional method which can\nincorporate the full backreaction of the field on the atom, while adopting\nGrassmannian variables for the 2LA and the coherent state representation for\nthe EMF. We find exact master equations for the cases of a free quantum field\nand a cavity field in the vacuum. In response to the search for mechanisms to\npreserve maximal coherence in quantum computations in ion trap prototypes, we\napply these equations to analyse the decoherence of a 2LA in an EMF, and fine\nthat decoherence time is close to relaxation time. This is at variance to the\nclaims by authors who studied the same system but used a different coupling\nmodel. We explain the source of difference and argue that, contrary to common\nbelief, the EMF when resonantly coupled to an atom does not decohere it as\nefficiently as a bath does on a quantum Brownian particle. The master-equations\nfor non-Markovian dynamics derived here is expected to be useful for exploring\nnew regimes of 2LA-EMF interaction, which is becoming physically important\nexperimentally.",
"arxiv_id": "quant-ph/9901078",
"authors": [
"Charis Anastopoulos",
"B. L. Hu"
],
"categories": [
"quant-ph"
],
"doi": "10.1103/PhysRevA.62.033821",
"journal_ref": "Phys.Rev.A62:033821,2000",
"title": "Two - Level Atom - Field Interaction: Exact Master Equations for Non-Markovian Dynamics, Decoherence and Relaxation",
"url": "https://arxiv.org/abs/quant-ph/9901078"
},
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