Ion–laser interactions: The most complete solution

Moya‐Cessa, H.; Soto‐Eguibar, Francisco; Vargas-Martínez, J.M.; Juárez-Amaro, R.; Zúñiga-Segundo, Arturo

doi:10.1016/j.physrep.2012.01.002

Cited by 53 publications

(55 citation statements)

References 78 publications

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“…We studied the ideal case of light-matter interaction (i.e., where no interaction of the total system with an environment takes place; see for instance [15]); however, because we are considering initial states with only diagonal terms in the field density matrix, it is expected that for sufficiently small cavity decay, our study describes the interaction well, as the environment severely affects off-diagonal matrix elements, quickly destroying coherent effects. Finally, effects such as the decrease of entropy of a subsystem by swapping purity could also be realized in ion-laser interaction [9,10] and semiconductor microcavities [16], to name some other possibilities.…”

Section: Discussionmentioning

confidence: 99%

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Entropy for the Quantized Field in the Atom-Field Interaction: Initial Thermal Distribution

Andrade-Morales

Villegas-Martínez

Moya‐Cessa

2016

Entropy

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Abstract:We study the entropy of a quantized field in interaction with a two-level atom (in a pure state) when the field is initially in a mixture of two number states. We then generalise the result for a thermal state; i.e., an (infinite) statistical mixture of number states. We show that for some specific interaction times, the atom passes its purity to the field and therefore the field entropy decreases from its initial value.

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Section: Discussionmentioning

confidence: 99%

“…Although we are considering here a two-level atom interacting with a quantised field, these kinds of Hamiltonians may also be realized in ion-laser interactions [9,10].…”

Section: Initial Mixed Statementioning

confidence: 99%

Entropy for the Quantized Field in the Atom-Field Interaction: Initial Thermal Distribution

Andrade-Morales

Villegas-Martínez

Moya‐Cessa

2016

Entropy

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“…The trapped-ion total Hamiltonian then takes the form (cf., e. g., [10], [11]) (2) where parameter K = λE L has been introduced.…”

Section: Minimal Form Of the Trapped-ion Modelmentioning

confidence: 99%

“…The intense theoretical work on these systems and the parallel experimental progress in ion trapping are thoroughly reviewed in [1] and [8]- [10].…”

Section: Introductionmentioning

confidence: 99%

Perturbative approach to the dynamics of a trapped ion interacting with a light field

Penna¹,

Raffa²

2014

J. Phys. B: At. Mol. Opt. Phys.

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We present a second-order perturbative analysis of the model describing a two-level trapped ion interacting with a traveling laser field, in the Lamb-Dicke regime. Unlike the customary approach, based on the interaction picture and the rotating wave approximation, we reduce the original Hamiltonian to a time-independent model, unitarily equivalent to a spin-boson model, which features a form well suited to apply the perturbation theory. We determine the first and second-order corrections of eigenstates and eigenvalues. By varying the interaction parameters we identify four regimes characterized by different eigenvalue distributions (possibly including level doublets) and suggest the presence of an intermediate regime where the spectrum undergoes macroscopic changes. In this regime, where the perturbation approach does not hold, our reduced Hamiltonian is shown to reproduce the Jaynes-Cummings model.

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“…[10][11][12][13]). Thus we would like to know whether the entanglement can be generated in the systems of macroscopic mechanical resonators.…”

Section: Introductionmentioning

confidence: 99%

Entangled-state engineering of vibrational modes in a multimembrane optomechanical system

Zhao

Liu

2013

Phys. Rev. A

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We propose a method to generate entangled states of the vibrational modes of N membranes which are coupled to a cavity mode via the radiation pressure. Using sideband excitations, we show that arbitrary entangled states of vibrational modes of different membranes can be produced in principle by sequentially applying a series of classical pulses with desired frequencies, phases and durations. As examples, we show how to synthesize several typical entangled states, for example, Bell states, NOON states, GHZ states and W states. The environmental effect, information leakage, and experimental feasibility are briefly discussed. Our proposal can also be applied to other experimental setups of optomechanical systems, in which many mechanical resonators are coupled to a common sing-mode cavity field via the radiation pressure.

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Ion–laser interactions: The most complete solution

Cited by 53 publications

References 78 publications

Entropy for the Quantized Field in the Atom-Field Interaction: Initial Thermal Distribution

Entropy for the Quantized Field in the Atom-Field Interaction: Initial Thermal Distribution

Perturbative approach to the dynamics of a trapped ion interacting with a light field

Entangled-state engineering of vibrational modes in a multimembrane optomechanical system

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