Your search keyword '"Giacomo Balistreri"' showing total 9 results

1. Scanless Spectral Imaging of Terahertz Vortex Beams Generated by High‐Resolution 3D‐Printed Spiral Phase Plates

Author

Andreea Aura Paraipan, Diana Gonzalez‐Hernandez, Innem V. A. K. Reddy, Giacomo Balistreri, Luca Zanotto, Mostafa Shalaby, Roberto Morandotti, Carlo Liberale, and Luca Razzari

Subjects

high‐resolution 3D printing, scanless terahertz hyperspectral imaging, spiral phase plate, terahertz vortex beam, two‐photon polymerization lithography, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Terahertz technology has experienced significant advances in the past years, leading to new applications in the fields of spectroscopy, imaging, and communications. This progress requires the development of dedicated optics to effectively direct, control and manipulate terahertz radiation. In this regard, 3D printing technologies have shown great potential, offering fast prototyping, high design flexibility, and good reproducibility. While traditional 3D printing techniques allow for the preparation of terahertz optical components operating at relatively low frequencies (

Published

2024

2. Metalens-Based Compressed Ultracompact Femtophotography: Analytical Modeling and Simulations

Author

Miguel Marquez, Giacomo Balistreri, Roberto Morandotti, Luca Razzari, and Jinyang Liang

Subjects

Physics, QC1-999, Applied optics. Photonics, TA1501-1820

Abstract

Single-shot 2-dimensional optical imaging of transient phenomena is indispensable for numerous areas of study. Among existing techniques, compressed ultrafast photography (CUP) using a chirped ultrashort pulse as active illumination can acquire nonrepetitive time-evolving events at hundreds of trillions of frames per second. However, the bulky size and conventional configurations limit its reliability and application scopes. Superdispersive metalenses offer a promising solution for an ultracompact design with a stable performance by integrating the functions of a focusing lens and dispersive optical components into a single device. Nevertheless, existing metalens designs, typically optimized for the full visible spectrum with a relatively low spectral resolution, cannot be readily applied to active-illumination CUP. To address these limitations, here, we propose single-shot compressed ultracompact femtophotography (CUF) that synergically combines the fields of nanophotonics, optical imaging, compressed sensing, and deep learning. We develop the theory of CUF’s data acquisition composed of temporal–spectral mapping, spatial encoding, temporal shearing, and spatiotemporal integration. We also develop CUF’s image reconstruction via deep learning. Moreover, we design and evaluate CUF’s crucial components—a static binary transmissive mask, a superdispersive metalens, and a 2-dimensional sensor. Finally, using numerical simulations, CUF’s feasibility is verified using 2 synthetic scenes: an ultrafast beam sweeping across a surface and the propagation of a terahertz Cherenkov wave.

Published

2024

3. Versatile metal-wire waveguides for broadband terahertz signal processing and multiplexing

Author

Junliang Dong, Alessandro Tomasino, Giacomo Balistreri, Pei You, Anton Vorobiov, Étienne Charette, Boris Le Drogoff, Mohamed Chaker, Aycan Yurtsever, Salvatore Stivala, Maria A. Vincenti, Costantino De Angelis, Detlef Kip, José Azaña, and Roberto Morandotti

Subjects

Science

Abstract

Waveguides that can provide complex signal-processing functionalities while guiding terahertz signals are desired. Here, the authors report the independent processing of multiplexed signals by engineering the metal surface of a four-wire waveguide.

Published

2022

4. Broadband Terahertz Signal Processing and Multiplexing with Four-wire Waveguides

Author

Junliang Dong, Alessandro Tomasino, Giacomo Balistreri, Pei You, Anton Vorobiov, Aycan Yurtsever, Salvatore Stivala, Maria A. Vincenti, Costantino De Angelis, Detlef Kip, José Azaña, and Roberto Morandotti

Abstract

We demonstrate a new waveguide geometry, namely a four-wire waveguide, which acts as a terahertz polarization-division multiplexer and a novel platform to realize versatile signal-processing functionalities into independent channels over a broadband terahertz frequency range.

Published

2022

5. Versatile metal-wire waveguides for broadband terahertz signal processing and multiplexing

Author

Junliang Dong, Alessandro Tomasino, Giacomo Balistreri, Pei You, Anton Vorobiov, Étienne Charette, Boris Le Drogoff, Mohamed Chaker, Aycan Yurtsever, Salvatore Stivala, Maria A. Vincenti, Costantino De Angelis, Detlef Kip, José Azaña, Roberto Morandotti, Dong J., Tomasino A., Balistreri G., You P., Vorobiov A., Charette E., Le Drogoff B., Chaker M., Yurtsever A., Stivala S., Vincenti M.A., De Angelis C., Kip D., Azana J., and Morandotti R.

Subjects

Multidisciplinary, Science, Physics::Optics, General Physics and Astronomy, General Chemistry, Terahertz signal processing, Terahertz multiplexing, Waveguides, Settore ING-INF/01 - Elettronica, General Biochemistry, Genetics and Molecular Biology

Abstract

Waveguides play a pivotal role in the full deployment of terahertz communication systems. Besides signal transporting, innovative terahertz waveguides are required to provide versatile signal-processing functionalities. Despite fundamental components, such as Bragg gratings, have been recently realized, they typically rely on complex hybridization, in turn making it extremely challenging to go beyond the most elementary functions. Here, we propose a universal approach, in which multiscale-structured Bragg gratings can be directly etched on metal-wires. Such an approach, in combination with diverse waveguide designs, allows for the realization of a unique platform with remarkable structural simplicity, yet featuring unprecedented signal-processing capabilities. As an example, we introduce a four-wire waveguide geometry, amenable to support the low-loss and low-dispersion propagation of polarization-division multiplexed terahertz signals. Furthermore, by engraving on the wires judiciously designed Bragg gratings based on multiscale structures, it is possible to independently manipulate two polarization-division multiplexed terahertz signals. This platform opens up new exciting perspectives for exploiting the polarization degree of freedom and ultimately boosting the capacity and spectral efficiency of future terahertz networks.

Published

2021

6. Time-Domain Integration of Terahertz pulses

Author

Aycan Yurtsever, Roberto Morandotti, Alessandro Tomasino, Junliang Dong, Salvatore Stivala, Giacomo Balistreri, José Azaña, Tomasino A., Balistreri G., Dong J., Yurtsever A., Stivala S., Azana J., and Morandotti R.

Subjects

Physics, Waveguide (electromagnetism), business.industry, Terahertz radiation, Physics::Optics, Electromagnetic radiation, Settore ING-INF/01 - Elettronica, Terahertz spectroscopy and technology, Terahertz, Time-Domain Integration, symbols.namesake, Optical rectification, Fourier transform, symbols, Optoelectronics, Heterodyne detection, Time domain, business

Abstract

We report on the time-domain integration of terahertz pulses obtained via the tight confinement of the radiation in a tapered two-wire waveguide. Both simulation and experimental results prove the time integration capability of this structure.

Published

2021

7. Tapered Two-Wire Waveguide for Time-Domain Integration of Broadband Terahertz Pulses

Author

Salvatore Stivala, Junliang Dong, José Azaña, Aycan Yurtsever, Alessandro Tomasino, Giacomo Balistreri, Roberto Morandotti, Tomasino A., Balistreri G., Dong J., Yurtsever A., Stivala S., Azana J., and Morandotti R.

Subjects

Physics, business.industry, Terahertz radiation, Physics::Optics, Topology (electrical circuits), Terahertz spectroscopy and technology, symbols.namesake, Fourier transform, Broadband, symbols, Optoelectronics, Waveguide (acoustics), Time domain, Heterodyne detection, Terahertz, Time-domain integration, Waveguides, business, Nonlinear Sciences::Pattern Formation and Solitons

Abstract

We show the time-domain integration of terahertz pulses achieved in a sub-wavelength, tapered two-wire waveguide. Both simulation and experimental results prove the time integration functionality of this waveguide topology.

Published

2021

8. Time‐Domain Integration of Broadband Terahertz Pulses in a Tapered Two‐Wire Waveguide

Author

José Azaña, Junliang Dong, Giacomo Balistreri, Salvatore Stivala, Alessandro Tomasino, Aycan Yurtsever, Roberto Morandotti, Balistreri G., Tomasino A., Dong J., Yurtsever A., Stivala S., Azana J., and Morandotti R.

Subjects

Materials science, ultrafast optics, Terahertz radiation, business.industry, nonlinear optics, Ultrafast optics, Nonlinear optics, Condensed Matter Physics, THz radiation, Settore ING-INF/01 - Elettronica, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Optics, All-optical signal processing, Thz radiation, Broadband, Waveguide (acoustics), Time domain, THz waveguides, business

Abstract

In this work, the time-domain integration of broadband terahertz (THz) pulses via a tapered two-wire waveguide (TTWWG) is reported. Such a guiding structure consists of two metallic wires separated by a variable air gap that shrinks down to a subwavelength size as the movement takes from the waveguide input to its output. It is shown that while an input THz pulse propagates toward the subwavelength output gap, it is reshaped into its first-order time integral waveform. In order to prove the TTWWG time integration functionality, the THz pulse is detected directly within the output gap of the waveguide, so as to prevent the outcoupling diffraction from altering the shape of the time-integrated THz transient. Since the time-domain integration is due to the tight geometrical confinement of the THz radiation in a subwavelength gap volume, the TTWWG operational spectral range can easily be tuned by judiciously changing both the output gap size and the tapering angle. The results lead to the physical realization of a broadband, analog THz time integrator device, which is envisioned to serve as a key building block for the implementation of complex and ultrahigh-speed analog signal processing operations in THz communication systems.

Published

2021

9. Terahertz time-domain spectroscopy based on photoconductive antennas

Author

Giacomo Balistreri, Tomasino, A., Salvatore Stivala, Livreri, Patrizia, Busacca, Alessandro C., Alfonso Carmelo Cino, Balistreri, G, Tomasino, A, Stivala, S, Livreri, P, Busacca, A, and Cino, AC

Subjects

Terahertz time-domain spectroscopy, Settore ING-INF/02 - Campi Elettromagnetici, Photoconductive antennas, Settore ING-INF/01 - Elettronica

Abstract

In this work, we present our first experimental results obtained by means of a THz-TDS setup based on photoconductive antennas (PCAs). The main elements of the setup are: i) a mode-locked Ti:Sapphire femtosecond laser (Mai-Tai SP - Spectra Physics), providing optical pulses at 800±20 nm with a duration < 50 fs and repetition rate of 84 MHz; ii) two photoconductive antennas, made in LT-GaAs (Low-Grown Temperature Gallium Arsenide), operating as THz emitter and detector; iii) an optical delay line.