Geometrical Aberration Suppression for Large Aperture Sub-THz Lenses

Geometrical Aberration Suppression for Large Aperture Sub-THz Lenses

Advanced THz setups require high performance optical elements with large numerical apertures and small focal lengths. This is due to the high absorption of humid air and relatively low efficiency of commercially available detectors. Here, we propose a new type of double-sided sub-THz diffractive opt...

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Bibliographic Details
Published in:Journal of infrared, millimeter and terahertz waves Vol. 38; no. 3; pp. 347 - 355
Main Authors: Rachon, M., Liebert, K., Siemion, A., Bomba, J., Sobczyk, A., Knap, W., Coquillat, D., Suszek, J., Sypek, M.
Format: Journal Article
Language:English
Published: New York Springer US 01-03-2017
Springer Nature B.V
Springer Verlag
Subjects:
Aberration
Algorithms
Classical Electrodynamics
Design optimization
Diffractive optical elements
Electrical Engineering
Electronics and Microelectronics
Engineering
General Physics
Instrumentation
Narrowband
Numerical aperture
Optical components
Phase distribution
Physics
Three dimensional printing
Sub-terahertz
Kinoform
Double-sided lens
Diffractive lens
3D printing
Narrowband
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Summary:Advanced THz setups require high performance optical elements with large numerical apertures and small focal lengths. This is due to the high absorption of humid air and relatively low efficiency of commercially available detectors. Here, we propose a new type of double-sided sub-THz diffractive optical element with suppressed geometrical aberration for narrowband applications (0.3 THz). One side of the element is designed as thin structure in non-paraxial approach which is the exact method, but only for ideally flat elements. The second side will compensate phase distribution differences between ideal thin structure and real volume one. The computer-aided optimization algorithm is performed to design an additional phase distribution of correcting layer assuming volume designing of the first side of the element. The experimental evaluation of the proposed diffractive component created by 3D printing technique shows almost two times larger performance in comparison with uncorrected basic diffractive lens.
ISSN:1866-6892
1866-6906
DOI:10.1007/s10762-016-0342-1