Precise position measurement of an atom using superposition of two standing wave fields

M. Idrees; B. A. Bacha; M. Javed; S. A. Ullah

doi:10.1088/1555-6611/aa5680

Precise position measurement of an atom using superposition of two standing wave fields

M. Idrees, B. A. Bacha, M. Javed, S. A. Ullah

Research output: Contribution to journal › Article › peer-review

16 Citations (Scopus)

Abstract

We present a scheme that provides a strong basis for precise localization of atoms, using superposition of two standing wave fields in a three level λ-type gain assisted model. We show how atomic interference and diffraction occur at a particular node or antinode region of the standing wave fields. Two, three, four and even single localized peaks of atoms are observed in both full-wavelength and sub-half-wavelength domains, with 100 percent localization probability in a single peak. Dark lines appearing in the node region of the standing wave fields show strong evidence for atomic destructive interference. The proposed scheme allows for efficient localization of an atom to a particular point.

Original language	English
Article number	045202
Journal	Laser Physics
Volume	27
Issue number	4
DOIs	https://doi.org/10.1088/1555-6611/aa5680
Publication status	Published - Apr 2017
Externally published	Yes

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abstract = "We present a scheme that provides a strong basis for precise localization of atoms, using superposition of two standing wave fields in a three level λ-type gain assisted model. We show how atomic interference and diffraction occur at a particular node or antinode region of the standing wave fields. Two, three, four and even single localized peaks of atoms are observed in both full-wavelength and sub-half-wavelength domains, with 100 percent localization probability in a single peak. Dark lines appearing in the node region of the standing wave fields show strong evidence for atomic destructive interference. The proposed scheme allows for efficient localization of an atom to a particular point.",

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AU - Idrees, M.

AU - Bacha, B. A.

AU - Javed, M.

AU - Ullah, S. A.

PY - 2017/4

Y1 - 2017/4

N2 - We present a scheme that provides a strong basis for precise localization of atoms, using superposition of two standing wave fields in a three level λ-type gain assisted model. We show how atomic interference and diffraction occur at a particular node or antinode region of the standing wave fields. Two, three, four and even single localized peaks of atoms are observed in both full-wavelength and sub-half-wavelength domains, with 100 percent localization probability in a single peak. Dark lines appearing in the node region of the standing wave fields show strong evidence for atomic destructive interference. The proposed scheme allows for efficient localization of an atom to a particular point.

AB - We present a scheme that provides a strong basis for precise localization of atoms, using superposition of two standing wave fields in a three level λ-type gain assisted model. We show how atomic interference and diffraction occur at a particular node or antinode region of the standing wave fields. Two, three, four and even single localized peaks of atoms are observed in both full-wavelength and sub-half-wavelength domains, with 100 percent localization probability in a single peak. Dark lines appearing in the node region of the standing wave fields show strong evidence for atomic destructive interference. The proposed scheme allows for efficient localization of an atom to a particular point.

KW - atom localization

KW - quantum coherence

KW - three level atom

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VL - 27

JO - Laser Physics

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IS - 4

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ER -

Precise position measurement of an atom using superposition of two standing wave fields

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