Efficient two-dimensional atom localization via an external coherent magnetic field

Shui, Tao; Wang, Zhiping; Yu, Benli

doi:10.1007/s11128-014-0899-3

Cited by 5 publications

(1 citation statement)

References 40 publications

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“…Note that the quantum coherence and interference play a fundamental role in many other phenomena of atomic physics * hamid.hamedi@tfai.vu.lt † gediminas.juzeliunas@tfai.vu.lt and quantum optics, such as an electromagnetically induced transparency (EIT) [13][14][15][16][17][18], superluminal light propagation [19][20][21][22], optical bistability [23,24], Kerr nonlinearity [25,26], and others [27][28][29]. More recently, some schemes have been put forward for two-dimensional (2D) atom localization [30][31][32][33][34][35][36][37][38][39][40][41][42]. Ding et al [31] investigated the atom localization by monitoring the probe absorption in a microwave-driven fourlevel atomic medium affected by two orthogonal standingwave fields.…”

Section: Introductionmentioning

confidence: 99%

Phase-sensitive atom localization for closed-loop quantum systems

Hamedi

Juzeliūnas

2016

Phys. Rev. A

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A scheme of high-precision two-and three-dimensional (3D) atom localization is proposed and analyzed by using a density matrix method for a five-level atom-light coupling scheme. In this system four strong laser components (which could be standing waves) couple a pair of atomic internal states to another pair of states in all possible ways to form a closed-loop diamond-shape configuration of the atom-light interaction. By systematically solving the density matrix equations of the motion, we show that the imaginary part of the susceptibility for the weak probe field is position dependent. As a result, one can obtain information about the position of the atom by measuring the resulting absorption spectra. Focusing on the signatures of the relative phase of the applied fields stemming from the closed-loop structure of the diamond-shape subsystem, we find out that there exists a significant phase dependence of the eigenvalues required to have a maximum in the probe absorption spectra. It is found that by properly selecting the controlling parameters of the system, a nearly perfect 2D atom localization can be obtained. Finally, we numerically explore the phase control of 3D atom localization for the present scheme and show the possibility to obtain 1/2 detecting probability of finding the atom at a particular volume in 3D space within one period of standing waves.

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Section: Introductionmentioning

confidence: 99%

Phase-sensitive atom localization for closed-loop quantum systems

Hamedi

Juzeliūnas

2016

Phys. Rev. A

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High-precision three-dimensional atom localization in a three-level pump–probe atomic system

Zheng

Wang

2018

Can. J. Phys.

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We propose a new scheme for three-dimensional (3D) atom localization controlled by incoherent pump in a three-level Λ-type atomic system. The spatial position information of an atom in 3D space can be achieved via measuring probe gain and absorption when the atom passes through three mutually perpendicular standing-wave fields. It is found that high-detecting-probability and high-precision 3D atom localization can be obtained via properly adjusting the relevant parameters in the presence of the combination of a traveling-wave field and three orthogonal standing-wave fields. Furthermore, it is also shown that the incoherent pumping field can switch the localization patterns from the probe-gain sphere to the probe-absorption sphere and enhance 3D atom-localization precision.

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Two-dimensional atom localization via a combination of the standing-wave and Gaussian fields

Abd-Elnabi

2020

Int. J. Quantum Inform.

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The localization of atom is studied in two-dimensional (2D) in a four-level V-type atomic system by using the Gaussian field. The atom localization is investigated through the absorption spectrum of the weak probe field inside two orthogonal standing-wave fields. We consider three hypotheses for the interaction between the atom and fields (standing-wave and Gaussian fields), each hypothesis is considered individually. We obtain the expression for the first-order approximation of the absorption of the probe field mathematically for the hypothesis (I). The Gaussian field parameter plays an important role in the precision of the atom localization. The 2D atom localization can be dependent on the detuning of the probe field (resonance and off-resonance), the Rabi frequencies and the phase shifts.

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Efficient two-dimensional atom localization via an external coherent magnetic field

Cited by 5 publications

References 40 publications

Phase-sensitive atom localization for closed-loop quantum systems

Phase-sensitive atom localization for closed-loop quantum systems

High-precision three-dimensional atom localization in a three-level pump–probe atomic system

Two-dimensional atom localization via a combination of the standing-wave and Gaussian fields

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