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Abstracts
2-D(Two-dimensional) isotropic negative refractive
index (NRI) is explicitly realized via the orthogonal
signal and coupling standing-wave fields coupling the Ntype
four-level atomic system. Under some key parameters
of the dense vapour media, the atomic system exhibits
isotropic NRI with simultaneous negative permittivity
and permeability (i.e. left-handedness) in the 2-D x-y
plane. Compared with other 2-D NRI schemes, the coherent
atomic vapour media in our scheme may be an ideal
2-D isotropic NRI candidate and has some potential advantages,
significance or applications in the further investigation.
index (NRI) is explicitly realized via the orthogonal
signal and coupling standing-wave fields coupling the Ntype
four-level atomic system. Under some key parameters
of the dense vapour media, the atomic system exhibits
isotropic NRI with simultaneous negative permittivity
and permeability (i.e. left-handedness) in the 2-D x-y
plane. Compared with other 2-D NRI schemes, the coherent
atomic vapour media in our scheme may be an ideal
2-D isotropic NRI candidate and has some potential advantages,
significance or applications in the further investigation.
Publisher
Journal
Year
Volume
Issue
Physical description
Dates
received
23 - 5 - 2015
online
30 - 11 - 2015
accepted
6 - 10 - 2015
Contributors
author
-
Physics department,
Kunming University of Science and Technology, Kunming, 650500,
PR China
author
-
College English department, Kunming University of
Science and Technology, Kunming, 650500, PR China
author
-
Physics department,
Kunming University of Science and Technology, Kunming, 650500,
PR China
References
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Document Type
Publication order reference
Identifiers
YADDA identifier
bwmeta1.element.-psjd-doi-10_1515_phys-2015-0043
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