1. Terahertz focusing properties of polymeric zone plates characterized by a modified knife-edge technique
- Author
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Silvia Tofani, Renato Fastampa, Romeo Beccherelli, Dimitrios C. Zografopoulos, and Mauro Missori
- Subjects
Materials science ,Polymers ,Terahertz radiation ,Time domain analysis ,Efficiency ,Zone plate ,Edge (geometry) ,Diffraction efficiency ,01 natural sciences ,Electromagnetic radiation ,law.invention ,terahertz ,010309 optics ,Optics ,Stack (abstract data type) ,law ,0103 physical sciences ,zone plate ,Focusing ,diffractive lenses ,Parabolic reflector ,business.industry ,Statistical and Nonlinear Physics ,Atomic and Molecular Physics, and Optics ,Finite element method ,Terahertz spectroscopy ,Antennas ,business - Abstract
The focusing properties of a series of polymeric zone-plate lenses are investigated around a target frequency of 1 THz. Their characterization is performed by means of terahertz (THz) time-domain spectroscopy, employing a modified knife-edge technique that compensates for asymmetries of the impinging THz beam shape of typical photoconductive antenna-based THz sources. The samples are fabricated by a three-axis milling technique on slabs of an ultralow-loss cyclo-olefin polymer. Three different zone plates are studied, a conventional binary zone plate, a conventional four-level zone plate, and a recently introduced double-sided zone plate consisting of the stack of two phase-reversal binary zone plates, which is simpler to fabricate and less sensitive to mechanical damage than multilevel zone plates. Experimental results, coupled with finite element simulations, demonstrate that the double-sided zone plate features a resolution increased by about 3 lambda with respect to the binary zone plate and comparable with that of the four-level zone plate. The double-sided zone plate has 40% lower focusing efficiency and approximately 7 lambda shorter depth of field compared to its four-level counterpart. Nevertheless, it outperforms conventional binary zone plates by 25% in power focusing efficiency and features a 10 lambda longer depth of field. (C) 2019 Optical Society of America
- Published
- 2019
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