Thomas Bonazzi scite author profile

Thomas Bonazzi

2Publications

53Citation Statements Received

94Citation Statements Given

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Affiliations

PSL Research University, Université Paris Cité, École Normale Supérieure - PSL

Publications

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Absorption Engineering in an Ultrasubwavelength Quantum System

et al. 2020

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Many photonic and plasmonic structures have been proposed to achieve ultrasubwavelength light confinement across the electromagnetic spectrum. Notwithstanding this effort, however, the efficient funneling of external radiation into nanoscale volumes remains problematic. Here, we demonstrate a photonic concept that fulfills the seemingly incompatible requirements for both strong electromagnetic confinement and impedance matching to free space. Our architecture consists of antenna-coupled meta-atom resonators that funnel up to 90% of the incident radiation into an ultrasubwavelength semiconductor quantum well absorber of volume V = λ310–6. A significant fraction of the coupled electromagnetic energy is used to excite the electronic transitions in the quantum well, with a photon absorption efficiency 550 times larger than the intrinsic value of the electronic dipole. This system opens important perspectives for ultralow dark current quantum detectors and for the study of light–matter interaction in the extreme regimes of electronic and photonic confinement.

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10 Gbit s⁻¹ Free Space Data Transmission at 9 µm Wavelength With Unipolar Quantum Optoelectronics

Dely

Bonazzi

Spitz

et al. 2021

Laser & Photonics Reviews

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Free space optics data transmission with bitrate in excess of 10 Gbit s −1 is demonstrated at 9 µm wavelength by using a unipolar quantum optoelectronic system at room temperature, composed of a quantum cascade laser, a modulator, and a quantum cascade detector. The large frequency bandwidth of the system is set by the detector and the modulator that are both high frequency devices, while the laser emits in continuous wave. The amplitude modulator relies on the Stark shift of an absorbing optical transition in and out of the laser frequency. This device is designed to avoid charge displacement, and therefore it is characterized by an intrinsically large bandwidth and very low electrical power consumption. This demonstration of high-bitrate data transmission sets unipolar quantum devices as the most performing platform for the development of optoelectronic systems operating at very high frequency in the mid-infrared for several applications, such as digital communications and high-resolution spectroscopy.

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Thomas Bonazzi

Absorption Engineering in an Ultrasubwavelength Quantum System

10 Gbit s⁻¹ Free Space Data Transmission at 9 µm Wavelength With Unipolar Quantum Optoelectronics

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Thomas Bonazzi

Absorption Engineering in an Ultrasubwavelength Quantum System

10 Gbit s−1 Free Space Data Transmission at 9 µm Wavelength With Unipolar Quantum Optoelectronics

Contact Info

Product

Resources

About

10 Gbit s⁻¹ Free Space Data Transmission at 9 µm Wavelength With Unipolar Quantum Optoelectronics