Your search keyword '"Vilcot, A."' showing total 3 results

1. Ab Initio Study of the Crystalline Structure of HgS under Low and High Pressure.

Author

Aidouni, Ahmed Amine, Aissat, Abdelkader, Ould-Mohamed, Mounir, Benamar, Mohamed El Amine, Dupont, Samuel, and Vilcot, Jean Pierre

Abstract

This study analyzes the lattice dynamics of HgS under various pressures using ab initio self-consistent calculations based on the plane-wave method (PW) and generalized gradient approximation (GGA). The static study, performed by enthalpy calculations, predicts that the transition from the cinnabar phase (α-HgS) to the zinc-blende B3 (β-HgS) or wurtzite (2H) structures occurs at very low pressures, at 0.65 or 0.70 GPa, respectively. Furthermore, the transition from β-HgS to the rocksalt (B1) phase occurs at 7 GPa, and at high pressure, specifically at 110 GPa, HgS can adopt the CsCl (B2) phase. The mechanical study confirms the stability of the β and 2H phases at 0 GPa. Phonon calculations corroborate the results of the static and mechanical studies regarding stability ( α → 0.7 GPa 2 H → 0.9 GPa β) , and the results indicate that the instabilities of the transverse acoustic (TA) modes, induced by the application of pressures of 10.5 GPa, 21 GPa, and 190 GPa, are responsible for the observed phase transitions in part of the Brillouin. [ABSTRACT FROM AUTHOR]

Published

2024

2. Exploit the Bandwidth Capacities of the Perfluorinated Graded Index Polymer Optical Fiber for Multi-Services Distribution.

Author

Lethien, Christophe, Loyez, Christophe, Vilcot, Jean-Pierre, Rolland, Nathalie, and Rolland, Paul Alain

Subjects

POLYMER research, OPTICAL fibers, BANDWIDTHS, DATA transmission systems, DIGITAL communications, WIRELESS communications

Abstract

The study reported here deals with the exploitation of perfluorinated graded index polymer optical fiber bandwidth to add further services in a home/office network. The fiber properties are exhibited in order to check if perfluorinated graded index plastic optical fiber (PFGI-POF) is suitable to support a multiplexing transmission. According to the high bandwidth length of plastic fibers, both at 850 nm and 1,300 nm, the extension of the classical baseband existing network is proposed to achieve a dual concept, allowing the indoor coverage of wireless signals transmitted using the Radio over Fiber technology. The simultaneous transmission of a 10 GbE signal and a wireless signal is done respectively at 850 nm and 1,300 nm on a single plastic fiber using wavelength division multiplexing commercially available devices. The penalties have been evaluated both in digital (Bit Error Rate measurement) and radiofrequency (Error Vector Magnitude measurement) domains. [ABSTRACT FROM AUTHOR]

Published

2011

3. Plasmonic Layer as a Localized Temperature Control Element for Surface Plasmonic Resonance-Based Sensors.

Author

Ganesan, Sivaramakrishnan, Maricot, Sophie, Robillard, Jean-Francois, Okada, Etienne, Bakouche, Mohamed-Taieb, Hay, Laurent, and Vilcot, Jean-Pierre

Subjects

SURFACE plasmon resonance, OPTICAL measurements, REFRACTIVE index, THERMOGRAPHY, METALLIC films, WATER temperature, TEMPERATURE control

Abstract

Surface plasmon resonance (SPR) sensing is a well-established high-sensitivity, label-free and real-time detection technique for biomolecular interaction study. Its primary working principle consists of the measurement of the optical refractive index of the medium that is in close vicinity of the sensor surface. Bio-functionalization techniques allow biomolecular events to be located in such a way. Since optical refractive indices of any medium varies with the temperature, the place where the measurement takes place shall be within a temperature-controlled environment in order to ensure any temperature fluctuation is interpreted as a biomolecular event. Since the SPR measurement probes the sensed medium within the penetration depth of the plasmonic wave, which is less or in the order of 1 µm, we propose to use the metallic film constituting the detection surface as a localized heater aiming at controlling finely and quickly the temperature of the sensed medium. The Joule heating principle is then used and the modeling of the heater is reported as well as its validation by thermal IR imaging. Using water as a demonstration medium, SPR measurement results at different temperatures are successfully compared to the theoretical optical refractive index of water versus temperature. [ABSTRACT FROM AUTHOR]

Published

2021