Martino Aldrigo scite author profile

This paper presents the applications of the Hf 0.3 Zr 0.7 O 2 ferroelectric with a thickness of 10 nm for tuning high-frequency devices such as filters, phase shifters, and phased antenna arrays in the X band when the low bias voltages in the range À3 V-þ3 V are applied. In this respect, we show that a bandpass filter shifts its central frequency located at 10 GHz with 3 GHz, a phase shifter produces a phase difference of about 60 degrees in the X band, while the antenna array formed by two patched antennas is steering its lobe with 632 at 10 GHz. These results open the way for the tunability of high frequency devices for very low power applications, which represent one of the most challenging issues in applied physics. Published by AIP Publishing.

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Very large phase shift of microwave signals in a 6 nm Hf _x Zr_1−xO₂ ferroelectric at ±3 V

Dragoman

Modreanu²,

Povey³

et al. 2017

Nanotechnology

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In this letter, we report for the first time very large phase shifts of microwaves in the 1-10 GHz range, in a 1 mm long gold coplanar interdigitated structure deposited over a 6 nm Hf Zr O ferroelectric grown directly on a high resistivity silicon substrate. The phase shift is larger than 60° at 1 GHz and 13° at 10 GHz at maximum applied DC voltages of ±3 V, which can be supplied by a simple commercial battery. In this way, we demonstrate experimentally that the new ferroelectrics based on HfO could play an important role in the future development of wireless communication systems for very low power applications.

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Integration of Antenna Array and Self-Switching Graphene Diode for Detection at 28 GHz

Yasir

Aldrigo

Dragoman

et al. 2019

IEEE Electron Device Lett.

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Graphene rectenna for efficient energy harvesting at terahertz frequencies

Dragoman

Aldrigo

2016

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In this paper, we propose a graphene rectenna that encompasses two distinct functions in a single device, namely, antenna and rectifier, which till now were two separate components. In this way, the rectenna realizes an efficient energy harvesting technique due to the absence of impedance mismatch between antenna and diode. In particular, we have obtained a maximum conversion efficiency of 58.43% at 897 GHz for the graphene rectenna on n-doped GaAs, which is a very good value, close to the performance of an RF harvesting system. A comparison with a classical metallic antenna with an HfO2-based metal-insulator-metal diode is also provided.

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Martino Aldrigo

A tunable microwave slot antenna based on graphene

Extraordinary tunability of high-frequency devices using Hf0.3Zr0.7O2 ferroelectric at very low applied voltages

Very large phase shift of microwave signals in a 6 nm Hf _x Zr_1−xO₂ ferroelectric at ±3 V

Integration of Antenna Array and Self-Switching Graphene Diode for Detection at 28 GHz

Graphene rectenna for efficient energy harvesting at terahertz frequencies

Contact Info

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Resources

About

Martino Aldrigo

A tunable microwave slot antenna based on graphene

Extraordinary tunability of high-frequency devices using Hf0.3Zr0.7O2 ferroelectric at very low applied voltages

Very large phase shift of microwave signals in a 6 nm Hf x Zr1−x O2 ferroelectric at ±3 V

Integration of Antenna Array and Self-Switching Graphene Diode for Detection at 28 GHz

Graphene rectenna for efficient energy harvesting at terahertz frequencies

Contact Info

Product

Resources

About

Very large phase shift of microwave signals in a 6 nm Hf _x Zr_1−xO₂ ferroelectric at ±3 V