Your search keyword '"T. Verdot"' showing total 7 results

1. Biaxial Piezoelectric MEMS Mirrors with Low Absorption Coating for 1550 nm Long-Range LIDAR

Author

L. Mollard, J. Riu, S. Royo, C. Dieppedale, A. Hamelin, A. Koumela, T. Verdot, L. Frey, G. Le Rhun, G. Castellan, and C. Licitra

Subjects

quasi-static actuator, 2D MEMS mirror, piezoelectric, Bragg reflector, high power management, Mechanical engineering and machinery, TJ1-1570

Abstract

This paper presents the fabrication and characterization of a biaxial MEMS (MicroElectroMechanical System) scanner based on PZT (Lead Zirconate Titanate) which incorporates a low-absorption dielectric multilayer coating, i.e., a Bragg reflector. These 2 mm square MEMS mirrors, developed on 8-inch silicon wafers using VLSI (Very Large Scale Integration) technology are intended for long-range (>100 m) LIDAR (LIght Detection And Ranging) applications using a 2 W (average power) pulsed laser at 1550 nm. For this laser power, the use of a standard metal reflector leads to damaging overheating. To solve this problem, we have developed and optimised a physical sputtering (PVD) Bragg reflector deposition process compatible with our sol-gel piezoelectric motor. Experimental absorption measurements, performed at 1550 nm and show up to 24 times lower incident power absorption than the best metallic reflective coating (Au). Furthermore, we validated that the characteristics of the PZT, as well as the performance of the Bragg mirrors in terms of optical scanning angles, were identical to those of the Au reflector. These results open up the possibility of increasing the laser power beyond 2W for LIDAR applications or other applications requiring high optical power. Finally, a packaged 2D scanner was integrated into a LIDAR system and three-dimensional point cloud images were obtained, demonstrating the scanning stability and operability of these 2D MEMS mirrors.

Published

2023

2. COMPACT MODEL OF A MICRO ACCELEROMETER USING A PZR NANO-GAUGE SENSING ELEMENT

Author

Parent, Arnaud, C J Welham, C Dufour, S Rouvillois, S Louwers, P Rey, and T Verdot

Published

2019

3. Electrostatically driven optical Z-axis scanner with thermally bonded glass microlens

Author

T. Verdot, Christophe Gorecki, Karolina Laszczyk, L. El Fissi, Sylwester Bargiel, and Jorge Albero

Subjects

Microlens, Miniature confocal microscope, Bulk micromachining, Materials science, Glass microlens, Silicon, business.industry, SCOMOC, chemistry.chemical_element, General Medicine, Numerical aperture, MOEMS, Optics, chemistry, Focal length, Wafer, Microlens scanner, Silicon micromachining, Photonics, business, Raster scan, SU-8 bonding, Engineering(all)

Abstract

This paper presents a design, fabrication and characterization results of an electrostatically-actuated microlens scanner capable of precise positioning of integrated glass ball microlens along Z-axis. The device can be used in a wide range of photonic applications, e.g. in MOEMS microscopes for active changing of focal plane during 3-D raster scanning. The scanner construction is based on parallel-plate electrostatic actuation scheme where suspended silicon platform with integrated microlens (movable electrode) is attracted to silicon cover (fixed electrode). Both parts, fabricated individually by bulk micromachining of standard silicon wafer, are vertically aligned and bonded in low-temperature process through SU-8 film. The glass microlens with diameter of 360 μm, effective focal length of about 260 μm, and numerical aperture of 0.57, is directly thermally bonded in the centre of platform. The device demonstrates vertical displacement up to 26 μm in semi-static mode and 38 μm at dynamic mode ( f R = 540 Hz ) with the max. 160 V of applied excitation voltage.

Published

2010

4. New architecture of MEMS microphone for enhanced performances

Author

Jean-Louis Guyader, Ph Robert, E. Redon, Kerem Ege, Cécile Guianvarc'H, Arnaud Walther, Jaroslaw Czarny, B. Desloges, T. Verdot, Département Intégration Hétérogène sur Silicium (DIHS), Commissariat à l'énergie atomique et aux énergies alternatives (CEA), Laboratoire Vibrations Acoustique (LVA), Institut National des Sciences Appliquées de Lyon (INSA Lyon), Université de Lyon-Institut National des Sciences Appliquées (INSA)-Université de Lyon-Institut National des Sciences Appliquées (INSA), centre Lyonnais d'Acoustique (CeLyA), and Université de Lyon

Subjects

microphone, Fabrication, Scale (ratio), Microphone, Computer science, Acoustics, Boundary (topology), 02 engineering and technology, 01 natural sciences, acoustic, multiphysics simulations I, sensor, 0103 physical sciences, Electronic engineering, [SPI.NANO]Engineering Sciences [physics]/Micro and nanotechnologies/Microelectronics, 010301 acoustics, [PHYS.MECA.VIBR]Physics [physics]/Mechanics [physics]/Vibrations [physics.class-ph], [SPI.ACOU]Engineering Sciences [physics]/Acoustics [physics.class-ph], Microelectromechanical systems, Plane (geometry), Process (computing), [SPI.MECA.VIBR]Engineering Sciences [physics]/Mechanics [physics.med-ph]/Vibrations [physics.class-ph], multiphysics simulations, 021001 nanoscience & nanotechnology, [PHYS.MECA.ACOU]Physics [physics]/Mechanics [physics]/Acoustics [physics.class-ph], MEMS, 0210 nano-technology, Microfabrication

Abstract

International audience; This paper describes the conception, designs consideration and fabrication process of a novel MEMS microphone. The presented microphone not only uses a new architecture, the sensitive part being beams moving within the plane of the substrate, but also uses an innovative detection means with Silicon piezo-resistive nanogauges. Modelization will consider acoustic and mechanical interactions. Besides, at MEMS scale, accurate simulation of the sensor must take into account thermal and viscous boundary layers in acoustics, and we will show that the presented sensor takes benefit from these short scale effects, which leads to achieve theoretical resolution as low as 24dB.

Published

2013

5. Downsizing and Silicon Integration of Photoacoustic Gas Cells

Author

A. Glière, P. Barritault, A. Berthelot, C. Constancias, J.-G. Coutard, B. Desloges, L. Duraffourg, J.-M. Fedeli, M. Garcia, O. Lartigue, H. Lhermet, A. Marchant, J. Rouxel, J. Skubich, A. Teulle, T. Verdot, and S. Nicoletti

Subjects

Trace gas measurements, MEMS, technology, industry, and agriculture, Silicon integration, Photoacoustic spectroscopy

Abstract

Downsizing and compatibility with MEMS silicon foundries is an attractive path towards a large diffusion of photoacoustic trace gas sensors. As the photoacoustic signal scales inversely with the chamber volume, a trend to miniaturization has been followed by several teams. We review in this article the approach initiated several years ago in our laboratory. Three generations of components, namely a 40 mm3 3D-printed cell, a 3.7 mm3 silicon cell, and a 2.3 mm3 silicon cell with a built-in piezoresistive pressure sensor, have been designed. The models used take into account the viscous and thermal losses, which cannot be neglected for such small-sized resonators. The components have been fabricated either by additive manufacturing or microfabrication and characterized. Based on a compilation of experimental data, a similar sub-ppm limit of detection is demonstrated. All three versions of photoacoustic cells have their own domain of operation as each one has benefits and drawbacks, regarding fabrication, implementation, and ease of use.

6. Biaxial Piezoelectric MEMS Mirrors with Low Absorption Coating for 1550 nm Long-Range LIDAR.

Author

Mollard L, Riu J, Royo S, Dieppedale C, Hamelin A, Koumela A, Verdot T, Frey L, Le Rhun G, Castellan G, and Licitra C

Abstract

This paper presents the fabrication and characterization of a biaxial MEMS (MicroElectroMechanical System) scanner based on PZT (Lead Zirconate Titanate) which incorporates a low-absorption dielectric multilayer coating, i.e., a Bragg reflector. These 2 mm square MEMS mirrors, developed on 8-inch silicon wafers using VLSI (Very Large Scale Integration) technology are intended for long-range (>100 m) LIDAR (LIght Detection And Ranging) applications using a 2 W (average power) pulsed laser at 1550 nm. For this laser power, the use of a standard metal reflector leads to damaging overheating. To solve this problem, we have developed and optimised a physical sputtering (PVD) Bragg reflector deposition process compatible with our sol-gel piezoelectric motor. Experimental absorption measurements, performed at 1550 nm and show up to 24 times lower incident power absorption than the best metallic reflective coating (Au). Furthermore, we validated that the characteristics of the PZT, as well as the performance of the Bragg mirrors in terms of optical scanning angles, were identical to those of the Au reflector. These results open up the possibility of increasing the laser power beyond 2W for LIDAR applications or other applications requiring high optical power. Finally, a packaged 2D scanner was integrated into a LIDAR system and three-dimensional point cloud images were obtained, demonstrating the scanning stability and operability of these 2D MEMS mirrors.

Published

2023

7. πFBG resonator used as a transducer for trace gas photothermal detection.

Author

Lauwers T, Glière A, Verdot T, and Basrour S

Abstract

We present an optical transduction method adapted to the detection of low frequency thermal perturbations and implemented for photothermal trace gas detection. The transducer is a π-phase shifted fiber Bragg grating, stabilized and interrogated by the Pound-Drever-Hall method. The principle of detection is based on the frequency shift of the narrow optical resonance, induced by the temperature variations. In temperature measurement mode, the stabilization leads to an estimated limit of detection of 1 µK at room temperature and at a frequency of 40 Hz. When the fiber transducer is placed in a gas cell, CO 2 is detected by photothermal spectroscopy with a limit of detection of 3 ppm/ H z . This novel method, based on a single fiber, offers robustness, stabilized operation and remote detection capability.

Published

2021