M. Rachon scite author profile

M. Rachon

5Publications

37Citation Statements Received

50Citation Statements Given

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Affiliations

Warsaw University of Technology

Publications

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Terahertz 3D printed diffractive lens matrices for field-effect transistor detector focal plane arrays

Nowakowski-Szkudlarek¹,

Sypek²,

Cywiński³

et al. 2016

Opt. Express

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We present the concept, the fabrication processes and the experimental results for materials and optics that can be used for terahertz field-effect transistor detector focal plane arrays. More specifically, we propose 3D printed arrays of a new type - diffractive multi-zone lenses of which the performance is superior to that of previously used mono-zone diffractive or refractive elements and evaluate them with GaN/AlGaN field-effect transistor terahertz detectors. Experiments performed in the 300-GHz atmospheric window show that the lens arrays offer both a good efficiency and good uniformity, and may improve the signal-to-noise ratio of the terahertz field-effect transistor detectors by more than one order of magnitude. In practice, we tested 3 × 12 lens linear arrays with printed circuit board THz detector arrays used in postal security scanners and observed significant signal-to-noise improvements. Our results clearly show that the proposed technology provides a way to produce cost-effective, reproducible, flat optics for large-size field-effect transistor THz-detector focal plane arrays.

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Geometrical Aberration Suppression for Large Aperture Sub-THz Lenses

Rachon¹,

Liebert²,

Siemion³

et al. 2016

J Infrared Milli Terahz Waves

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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.

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THz Beam Shaper Realizing Fan-Out Patterns

Liebert

Rachon

Siemion

et al. 2017

J Infrared Milli Terahz Waves

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Fan-out elements create an array of beams radiating at particular angles along the propagation axis. Therefore, they are able to form a matrix of equidistant spots in the far-field diffraction region. In this work, we report on the first fan-out structures designed for the THz range of radiation. Two types of light-dividing fan-out structures are demonstrated: (i) the 3×1 matrix fan-out structure based on the optimized binary phase grating and (ii) the 3×3 fan-out structure designed on the basis of the well-known Dammann grating. The structures were generated numerically and manufactured using the 3D printing technique with polyamide PA12. To obtain equal powers and symmetry of diffracted beams, the computer-aided optimization algorithm was used. Diffractive optical elements designed for 140 and 282 GHz were evaluated experimentally at both these frequencies using illumination with the wavefront coming from the point-like source. Described fan-out elements formed uniform intensity and equidistant energy distribution in agreement with the numerical simulations.

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Enhanced Sub-wavelength Focusing by Double-Sided Lens with Phase Correction in THz Range

Rachon

Liebert

But

et al. 2020

J Infrared Milli Terahz Waves

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High capacity radio lines operating in the sub-THz and THz ranges often require very efficient optical elements with a focal length to an aperture diameter ratio—f-number—less than 1. Here, we propose a new type of double-sided sub-THz focusing diffractive optical element with f-number equal to 0.2, designed for quasi-monochromatic illumination with carrier frequency equal to 170 GHz. The element is manufactured by 3D printing technology. Its focal spot diameter defined as the Airy disc size is comparable to the used wavelength. In order to optimize numerically the phase distribution on the anterior side of the structure, we proposed a novel idea based on reversal of phase distribution in outer zones with additional constant phase factor (a method called free form phase distribution, FFPD). Moreover, we applied the modified numerical algorithm to obtain an additional phase correction in a form of a corrective kinoform placed on the posterior side of the diffractive system. The resulted diffractive structure, illuminated by a quasi-plane wave, forms an extremely small focal spot. The paper presents the technical and the theoretical backgrounds, the results of the computer simulations and finally the experimental results.

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Efficiency of THz Paper Optical Elements Depending on their Type and Manufacturing Techniques.

Rachon

Węgrzyńska

Sypek

et al. 2015

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M. Rachon

Terahertz 3D printed diffractive lens matrices for field-effect transistor detector focal plane arrays

Geometrical Aberration Suppression for Large Aperture Sub-THz Lenses

THz Beam Shaper Realizing Fan-Out Patterns

Enhanced Sub-wavelength Focusing by Double-Sided Lens with Phase Correction in THz Range

Efficiency of THz Paper Optical Elements Depending on their Type and Manufacturing Techniques.

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