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2,153 results on '"Bouville, A."'

1. Tunable on-chip electro-optic frequency-comb generation at 8 {\mu}m wavelength

Author

Turpaud, Victor, Nguyen, Thi-Hao-Nhi, Koompai, Natnicha, Peltier, Jonathan, Frigerio, Jacopo, Calcaterra, Stefano, Coudevylle, Jean-René, Bouville, David, Alonso-Ramos, Carlos, Vivien, Laurent, Isella, Giovanni, and Marris-Morini, Delphine

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

Dual-comb spectroscopy is a powerful technique to measure optical spectra in a wide spectral range with high-frequency resolution. The development of compact systems operating in the long-wave infrared wavelength range is of high interest for spectroscopic and sensing applications. Amongst the different techniques to obtain optical frequency-combs, electro-optic frequency-comb generation presents major advantages thanks to the tunable repetition rate only limited by the bandwidth of the used electro-optical modulator. However, the development of integrated and efficient electro-optical modulators operating in a wide long-wave infrared spectral band is still at its infancy, and electro-optical frequency-comb has not been demonstrated so far beyond the telecom band. In this work, a Schottky-based modulator embedded in a Ge-rich graded SiGe waveguide is used for electro-optic frequency-comb generation. Considering the limited efficiency of the modulator, harmonically-rich RF signals are used to enhance the generation of comb lines around the optical carrier. Interestingly, this allows us to demonstrate the generation of electro-optical combs spanning over 2.4 GHz around 8 {\mu}m wavelength. This paves the way towards fully integrated and tunable mid-infrared electro-optic frequency-comb generation systems., Comment: 10 pages, 9 figures

Published
2024

2. Inorganic/inorganic composites through emulsion templating

Author

Jiang, Tianhui, Zhou, Shitong, Hong, Yinglun, Poloni, Erik, Saiz, Eduardo, and Bouville, Florian

Subjects
Condensed Matter - Materials Science
Abstract

Inorganic/inorganic composites are found in multiple applications crucial for the energy transition, from nuclear reactor to energy storage devices. Their microstructures dictate a number of properties, such as mass transport or fracture resistance. There has been a multitude of process developed to control the microstructure of inorganic/inorganic composites, from powder mixing and the use of short or long fibre, to tape casting for laminates up to recently 3D printing. Here, we combined emulsions and slip casting into a simpler, broadly available, inexpensive processing platform that allow for in situ control of a composite's microstructure that also enables complex shaping. Emulsions are used to form droplets of controllable size of one inorganic phase into another, while slip casting enable 3D shaping of the final part. Our study shows that slip casting emulsions trigger a two-steps solvent removal that opens the possibility for conformal coating of porosity. By making magnetically responsive droplets, we form inorganic fibre inside an inorganic matrix during slip casting, demonstrating a simple fabrication for long-fibre reinforced composites. We exemplify the potential of this processing platform by making strong and lightweight alumina scaffolds reinforced by a confirmed zirconia coating and alumina with metallic iron fibres that displays work of fracture an order of magnitude higher than alumina.

Published
2024

3. Order induces toughness in anisotropic colloidal crystal composites

Author

Vilchez, Victoria, Zhou, Shitong, and Bouville, Florian

Subjects
Condensed Matter - Materials Science, Condensed Matter - Soft Condensed Matter
Abstract

Spatial ordering of matter elicits exotic properties sometimes absent from a material's constituents. A few highly mineralised natural materials achieve high toughness through delocalised damage, whereas synthetic particulate composites must trade toughness for mineral content. We test whether ordering the mineral phase in particulate composites through the formation of macroscopic colloidal crystals can trigger the same damage resistance found in natural materials. Our macroscopic silica rod based anisotropic colloidal crystal composites are processed fully at room temperature and pressure, reach volume fraction of mineral higher than 80%, and aided by a ductile interface, unveil plastic strain reaching 10% through the collective movement of rods and damage delocalisation over millimetres. These composites demonstrate key design rules to break free from conventionally accepted structural materials properties trade-off.

Published
2024

6. Dispersive wave control enabled by silicon metamaterial waveguides

Author

Dinh, T. T. D., Roux, X. Le, Montesinos-Ballester, M., Lafforgue, C., Zhang, J., González-Andrade, D., Melati, D., Bouville, D., Benedikovic, D., Cheben, P., Cassan, E., Marris-Morini, D., Vivien, L., and Alonso-Ramos, C.

Subjects
Physics - Optics
Abstract

The ability to exploit the on-chip nonlinear generation of new frequencies has opened the door to a plethora of applications in fundamental and applied physics. Excitation of dispersive waves is a particularly interesting process that allows efficient nonlinear wavelength conversion by phase-matching of a soliton and waves in the normal dispersion regime. However, controlling the wavelength of dispersive waves in integrated waveguides remains an open challenge, hampering versatile shaping of the nonlinear spectral response. Here, we show that metamaterial silicon waveguides release new degrees of freedom to select the wavelength of dispersive waves. Based on this concept, we experimentally demonstrate excitation of two dispersive waves near 1.55 {\mu}m and 7.5 {\mu}m allowing ultra-wideband supercontinuum generation, covering most of the silicon transparency window. These results stand as an important milestone for versatile nonlinear frequency generation in silicon chips, with a great potential for applications in sensing, metrology and communications.

Published
2022

7. Carbon ablators with porosity designed for enhanced aerospace thermal protection

Author

Poloni, Erik, Bouville, Florian, Schmid, Alexander L., Pelissari, Pedro I. B. G. B., Pandolfelli, Victor C., Sousa, Marcelo L. C., Tervoort, Elena, Christidis, George, Shklover, Valery, Leuthold, Juerg, and Studart, André R.

Subjects
Physics - Applied Physics, Condensed Matter - Materials Science
Abstract

Porous carbon ablators offer cost-effective thermal protection for aerospace vehicles during re-entry into planetary atmospheres. However, the exploration of more distant planets requires the development of ablators that are able to withstand stronger thermal radiation conditions. Here, we report the development of bio-inspired porous carbon insulators with pore sizes that are deliberately tuned to enhance heat-shielding performance by increasing scattering of high-temperature thermal radiation. Pore size intervals that promote scattering are first estimated using an established model for the radiative contribution to the thermal conductivity of porous insulators. On the basis of this theoretical analysis, we identify a polymer additive that enables the formation of pores in the desired size range through the polymerization-induced phase separation of a mixture of phenolic resin and ethylene glycol. Optical and electron microscopy, porosimetry and mechanical tests are used to characterize the structure and properties of porous insulators prepared with different resin formulations. Insulators with pore sizes in the optimal scattering range reduce laser-induced damage of the porous structures by up to 42%, thus offering a promising and simple route for the fabrication of carbon ablators for enhanced thermal protection at high temperatures., Comment: 34 pages, 9 figures

Published
2021
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11. Microcalorimeter fabrication and new measurement methodology for thermal sensing in microfluidics

Author

Martina Freisa, Thi Hong Nhung Dinh, David Bouville, Laurent Couraud, Isabelle Le Potier, and Jean Gamby

Subjects
Resistance thermal detector, Microcalorimeter, Biosensor, Microfluidic device, Electronics, TK7800-8360, Technology (General), T1-995
Abstract

This work describes the integration of a Resistance Thermal Detector (RTD) microcalorimeter integrated into a 324 nL microfluidic channel. The sensor is fabricated in a clean room using photolithography and evaporation techniques, and it has a platinum serpentine with 60 windings. The RTDs undergo testing in the 30 to 45 °C temperature range, exhibiting great linearity and a sensitivity of 8.42 Ω/°C. Additionally, to perform the thermic measurement, we also provide a circuit architecture that ensures stability against external thermal fluctuations and the self-heating Joule effect. We showed that this measurement method allow us to achieve a precision of ±6.7·10−3 °C, compared to ±0.178 °C total fluctuations found by using the traditional 2-wire method.

Published
2023
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12. Detachable three-layer Au absorber microfabrication for low-temperature detectors

Author

Jawad Hadid, Matias Rodrigues, Abdelmounaim Harouri, Christophe Dupuis, David Bouville, Antoine Martin, Martin Loidl, and Laurence Ferlazzo

Subjects
Metallic magnetic calorimeters, Nanoporous surface, Gold nanofoam, Low-temperature detectors, Absorber, Electrodeposition, Electronics, TK7800-8360, Technology (General), T1-995
Abstract

Low temperature detectors (LTDs) used for decay energy spectrometry (DES) can provide accurate and reliable decay data thanks to their high-energy resolution and a near 100% detection efficiency for the radiations of interest. However, it is essential to consider the source quality to mitigate spectral distortion due to the self-absorption of particle energy in the source deposited.This work aimed to produce a replaceable 4π 3-layer gold absorber for DES in reusable metallic magnetic calorimeters, a class of LTDs. We present a novel 3-layer microfabrication process for a 1 mm diameter absorber with a total gold thickness ranging from 20 μm to 120 μm depending on the measured radionuclide (55Fe or 241Am). The absorber integrates a gold nanofoam in which the radionuclide is deposited by nanodrop deposition of a few tenths of μL of a radioactive solution. We fabricated a high quality gold nanofoam layer with controllable porosity through a dealloying process using wet etching and integrating it on a thick electrodeposited gold layer. The fine study of the nanofoam microfabrication is performed using high-resolution scanning electron microscopy (SEM) and energy dispersive x-ray spectroscopy (EDX).

Published
2023
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13. Optical modulation in Ge-rich SiGe waveguides in the mid-IR wavelength range up to 11 um

Author

Montesinos-Ballester, Miguel, Vakarin, Vladyslav, Ramirez, Joan Manel, Liu, Qiankun, Alonso-Ramos, Carlos, Roux, Xavier Le, Frigerio, Jacopo, Ballabio, Andrea, Barzaghi, Andrea, Deniel, Lucas, Bouville, David, Vivien, Laurent, Isella, Giovanni, and Marris-Morini, Delphine

Subjects
Physics - Optics, Physics - Applied Physics
Abstract

Waveguide integrated optical modulators in the mid-infrared (mid-IR) wavelength range are of significant interest for molecular spectroscopy in one hand, as on-chip synchronous detection can improve the performance of detection systems, and for free-space communications on the other hand, where optical modulators working in the atmospheric transparency windows are crucially missing. Here we report for the first time the demonstration of optical modulation in mid-IR photonic circuit reaching wavelengths larger than 8 um. Moreover, optical modulation in an unprecedented wavelength range, from 5.5 to 11 um wavelength is shown, relying on a broadband Ge-rich graded-SiGe platform. This first demonstration is used as a proof of concept, to experimentally confirm the free-carrier absorption effect modeling. These results pave the way towards efficient high-performance electrically-driven integrated optical modulators in the mid-IR wavelength range., Comment: 12 pages, 7 figures

Published
2019

16. Design principles for textured multi-layered composites using magnetically assisted slip casting

Author

Ferrand, Hortense Le, Bouville, Florian, and Studart, André R.

Subjects
Condensed Matter - Soft Condensed Matter
Abstract

In many natural multi-layered composites, such as in the dactyl club of Stomatopods or the shell of bivalve mollusks, the defining functional and structural properties are determined by locally varying orientations of inorganic building blocks within each layer. One approach to artificially produce textured microstructures inspired by such complex composites is magnetically assisted slip-casting (MASC). MASC is a colloidal process in which anisotropic particles are oriented at arbitrarily defined angles using a magnetic field. The orientation of the particles is maintained during growth as particles are collected from the wall of a porous mold. Whereas a number of proof-of-concept studies have established the potential of the technique, the full design space available for MASC-fabricated structures, and the limits of the approach, have so far not been explored in a systematic manner. To fill this gap, we have studied both theoretically and experimentally the various torques that act on the particles at different stage of the assembly process. We define the boundary conditions of the MASC process for magnetically responsive alumina platelets suspended in a low-viscosity aqueous suspension, considering the composition of the colloidal suspension and the dynamics of the particle-alignment process under a rotating magnetic field. Taken together, these findings define a design strategy for the fabrication of designed multi-lamellar microstructures using MASC. Our guidelines are based on a comprehensive understanding of the physical mechanisms governing the orientation and assembly of anisotropic particles during MASC and indicate a route to expanding this technique to building blocks of various chemistries, and thus to broadening the range of bio-inspired composites with customized multi-scale structures that can be produced for specific applications.

Published
2018

17. Processing of dense bio-inspired ceramics with deliberate microtexture

Author

Ferrand, Hortense Le, Bouville, Florian, and Studart, André R.

Subjects
Condensed Matter - Materials Science
Abstract

The architectures of biological hard materials reveal finely tailored complex assemblies of mineral crystals. Numerous recent studies associate the design of these local assemblies with impressive macroscopic response. Reproducing such exquisite control in technical ceramics conflicts with commonly used processing methods. Here, we circumvent this issue by combining the recently developed Magnetically-Assisted Slip Casting (MASC) technique with the well-established process of Templated Grain Growth (TGG). MASC enables the local control over the orientation of platelets dispersed among smaller isotropic particles. After a high temperature pressure-less treatment, the grains of the final ceramic follow the same orientation of the initial platelets. This combination allows us to produce 95 % dense alumina part with a grain orientation following any deliberate orientation. We successfully fabricated microstructures inspired from biological materials with ceramics that present periodically varying patterns with a programmable pitch of a few tens of microns. We confirmed the capacity of the process to tailor local mechanical properties through local grains orientation using micro-indentation. This micrometer scale control over the local mechanical properties could be applied to adapt ceramic structures to complex loads using this inexpensive and scalable process. In systems where functional properties also depend on anisotropic grain orientation, the principle presented here could enable the creation of new multifunctional ceramics.

Published
2018

18. Porous silicon carbide and aluminum oxide with unidirectional open porosity as model target materials for radioisotope beam production

Author

Czapski, M., Stora, T., Tardivat, Caroline, Deville, Sylvain, Augusto, R. Santos, Leloup, Jérôme, Bouville, Florian, and Luis, R. Fernandes

Subjects
Physics - Applied Physics
Abstract

New silicon carbide (SiC) and aluminum oxide (Al2O3) of a tailor-made microstructure were produced using the ice-templating technique, which permits controlled pore formation conditions within the material. These prototypes will serve to verify aging of the new advanced target materials under irradiation with proton beams. Before this, the evaluation of their mechanical integrity was made based on the energy deposition spectra produced by FLUKA codes., Comment: 8 pages, 3 figures

Published
2018
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21. Promoting ecological solutions for sustainable infrastructure

Author

Anders Sjölund, Yannick Autret, Marita Boettcher, Julie de Bouville, Lazaros E. Georgiadis, Elke Hahn, Agnès Hallosserie, Adam Hofland, Jean-François Lesigne, Antonio Mira, Charlotte Navarro, Carme Rosell, Tony Sangwine, Andreas Seiler, and Paul Wagner

Subjects
Linear infrastructure, biodiversity, ecosystems, Ecology, QH540-549.5, General. Including nature conservation, geographical distribution, QH1-199.5
Abstract

Linear infrastructure networks such as roads, railways, navigation and irrigation canals, and power lines have grown exponentially since the mid-20th century. Most of these networks built before the 1990s have a significant impact on the environment. While there is no doubt that humanity needs infrastructure to ensure safe, secure and sufficient access to food, water and energy, it is essential to prevent the loss of biodiversity and ecosystems which are also at the basis of the provision of such fundamental services. Those complex, interconnected issues cannot be tackled without research and innovation, both in the fields of biodiversity and of infrastructure.IENE (Infrastructure Ecology Network Europe) was set up in 1996 to meet this need. Its mission is to promote the exchange of knowledge, experience and best practice in safe and sustainable pan-European transport infrastructure. With a status of an association today, this independent network has more than 400 members consisting of researchers, engineers, decision makers and infrastructure operators. IENE functions as an international and interdisciplinary forum. It supports cross-border cooperation in research, mitigation, planning, design, construction and maintenance in the field of biodiversity and transport infrastructure.Every two years, IENE organises an international conference to present cutting-edge research, identify pressing issues and problems, discuss effective solutions and map out future activities in the field of transport ecology and infrastructure. We are very glad to present you in this special issue some of the best scientific outcomes of the IENE 2020 conference, hoping that it will contribute to further breakthroughs in science and uptake in policy-making and practices on the ground. We commend the organising team of the University of Evora, Portugal, for their excellent programming of the conference and for having gathered exceptional scientists on the topic of biodiversity and infrastructure. They managed to host a high-quality event, despite the many adjustments that had to be done because of the covid-19, including postponing the conference to January 2021 and holding it entirely online.The topic of IENE conference 2020 was “Linear Infrastructure Networks with Ecological Solutions” and the motto was “working together”. This means that every stakeholder has a role to play, and that biodiversity should be considered at all governance scales and during all phases of the set-up of infrastructure. The papers selected here are of particular interest to follow the path set forth in the conference’s final declaration, that is included in this issue.

Published
2022
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23. Dispersion of Boron Nitride Powders in Aqueous Suspensions with Cellulose

Author

Bouville, Florian and Deville, Sylvain

Subjects
Condensed Matter - Materials Science
Abstract

The dispersion of nitride and carbide ceramic particles in water is difficult, due to the absence of hydroxyl groups on their surface. Boron nitride is not an exception and despite its numerous applications, no effective dispersant has been identified so far. We demonstrate here the dispersion properties of two cellulose derivatives for hexagonal boron nitride powders, hydroxyl ethyl cellulose and methyl cellulose. The effect of particle sizes and cellulose concentration was investigated. The adsorption of cellulose onto the surface of the BN particles was confirmed by isotherm adsorption. Zeta potential measurements shows a charge screening effect of the cellulose The suspensions obtained were highly loaded and stable versus pH, and thus could lead to homogeneous codispersion of BN particles and sintering additives., Comment: 15 pages, 7 figures

Published
2017
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24. Reply to the correspondence: 'On the fracture toughness of bioinspired ceramic materials'

Author

Bouville, Florian, Maire, Eric, Meille, Sylvain, Van de Moortèle, Bertrand, Stevenson, Adam J., and Deville, Sylvain

Subjects
Condensed Matter - Materials Science
Abstract

This is a reply to the correspondence of Prof. Robert Ritchie: "On the fracture toughness of bioinspired ceramic materials", submitted to Nature Materials, which discusses the fracture toughness values of the following papers: Bouville, F., Maire, E., Meille, S., Van de Moort\`ele, B., Stevenson, A. J., & Deville, S. (2014). Strong, tough and stiff bioinspired ceramics from brittle constituents. Nature Materials, 13(5), 508-514 and Le Ferrand, H., Bouville, F., Niebel, T. P., & Studart, A. R. (2015). Magnetically assisted slip casting of bioinspired heterogeneous composites. Nature Materials, 14(11), 1172-1172., Comment: 5 pages, 2 figures

Published
2017

25. Tunable On‐Chip Electro‐Optic Frequency‐Comb Generation at 8 μm$\umu {\rm m}$ wavelength.

Author

Turpaud, Victor, Nguyen, Thi Hao Nhi, Koompai, Natnicha, Peltier, Jonathan, Frigerio, Jacopo, Calcaterra, Stefano, Coudevylle, Jean‐René, Bouville, David, Alonso‐Ramos, Carlos, Vivien, Laurent, Isella, Giovanni, and Marris‐Morini, Delphine

Subjects
INFANTS, WAVELENGTHS, PHOTONICS, BANDWIDTHS, SILICON
Abstract

The development of compact systems operating in the long‐wave infrared wavelength range is of high interest for spectroscopic and sensing applications. There is currently a wide interest toward the development of optical frequency‐combs to enhance the performances of these systems. Amongst the different techniques to obtain optical frequency‐combs, electro‐optic frequency‐comb generation presents major advantages thanks to the tunable repetition rate only limited by the bandwidth of the used electro‐optical modulator. However, the development of integrated and efficient electro‐optical modulators operating in a wide long‐wave infrared spectral band is still at its infancy, and electro‐optical frequency‐comb has not been demonstrated so far beyond 3 μm$\umu {\rm m}$ wavelength. In this work, a Schottky‐based modulator embedded in a Ge‐rich graded SiGe waveguide is used for electro‐optic frequency‐comb generation. Considering the limited efficiency of the modulator, harmonically‐rich RF signals are used to enhance the generation of comb lines around the optical carrier. Interestingly, this allows us to demonstrate the generation of electro‐optical combs spanning over 2.4 GHz around 8 μm$\umu {\rm m}$ wavelength. This paves the way toward fully integrated and tunable mid‐infrared electro‐optic frequency‐comb generation systems. [ABSTRACT FROM AUTHOR]

Published
2024
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27. Room Temperature‐Integrated Photodetector between 5 μm and 8 μm Wavelength

Author

Thi Hao Nhi Nguyen, Natnicha Koompai, Victor Turpaud, Miguel Montesinos-Ballester, Jacopo Frigerio, Stefano Calcaterra, Andrea Ballabio, Xavier Le Roux, Jean- René Coudevylle, Cédric Villebasse, David Bouville, Carlos Alonso-Ramos, Laurent Vivien, Giovanni Isella, and Delphine Marris-Morini

Subjects
germanium, integrated optics, mid-IR photonics, photodetection, silicon photonics, Applied optics. Photonics, TA1501-1820, Optics. Light, QC350-467
Abstract

Mid‐infrared (mid‐IR) optics has a great importance for a large number of applications in sensing, imaging, or even telecommunication. However, high‐speed and room‐temperature‐integrated photodetector (PD) operating in a wide spectrum of the mid‐IR is a critical device that is currently missing for the development of compact and efficient spectroscopic systems exploiting synchronous detection. Herein, a waveguide‐integrated PD based on a Schottky diode embedded in a graded silicon germanium waveguide is demonstrated. Photodetection is obtained in a wide spectral range from 5 to 8 μm wavelength, with responsivity reaching up to 0.1 mA W−1. Photodetection performed in pulsed regime with laser pulse width between 50 and 200 ns indicates an operation beyond 20 MHz. Interestingly, the achieved performances indicate that this device is already suitable for on‐chip signal monitoring, while further improvement can pave the way toward advanced compact and fully integrated spectroscopic systems operating in long‐wave infrared regions.

Published
2023
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28. 3D-printing of ceramic filaments with ductile metallic cores

Author

Qiaosong Cai, Sylvain Meille, Jérôme Chevalier, Shitong Zhou, Florian Bouville, Iuliia Tirichenko, and Eduardo Saiz

Subjects
Additive manufacturing, Composites, Ceramic, Metal, Toughness, Materials of engineering and construction. Mechanics of materials, TA401-492
Abstract

The additive manufacturing of composite structures can open possibilities in the design and fabrication of devices but also demands new approaches. In this work, we use thermally reversible pastes to fabricate ceramic matrix (Al2O3) composites reinforced with continuous metallic fibres (steel). The approach is based on the micro-extrusion of ceramic–metal filaments with core–shell and layered arrangements. These filaments are employed in the additive manufacturing of dense and light-weight cellular structures that combine the stiffness and strength of the ceramic shell with the fracture resistance and energy absorption capabilities provided by the metal core. The approach can be used to extrude filaments with thin porous interlayers separating the core and the shells to create a weak fibre/matrix interphase. The cellular structures fabricated with these filaments exhibit higher compressive strengths and energy absorption capabilities than those fabricated from pure ceramics. The works of fracture of the dense composites are one to two orders of magnitude above those of the ceramic matrix (103 J/m2) while the bending strengths remain comparable to those of 3D printed alumina (200–350 MPa). The technique could be easily extended to other material combinations opening new opportunities in the additive manufacturing of multi-material parts and devices.

Published
2023
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32. High Q-factor (>105) integrated resonators in the 7.5-9 µm wavelength range

Author

Koompai, Natnicha, primary, Nhi Nguyen, Thi Hao, additional, Turpaud, Victor, additional, Frigerio, Jacopo, additional, Falcone, Virginia, additional, Calcaterra, Stefano, additional, Lucia, Luca, additional, Bousseksou, Adel, additional, Colombelli, Raffaele, additional, Coudevylle, Jean-Rene, additional, Bouville, David, additional, Alonso-Ramos, Carlos, additional, Vivien, Laurent, additional, Isella, Giovanni, additional, and Marris-Morini, Delphine, additional

Published
2024
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35. Magnetically-Assisted Slip Casting of Bioinspired Heterogeneous Composites

Author

Ferrand, Hortense Le, Bouville, Florian, Niebel, Tobias P., and Studart, André R.

Subjects
Condensed Matter - Materials Science
Abstract

Composites are often made heterogeneous in nature to fulfill the functional demands imposed by the environment, but remain difficult to fabricate synthetically due to the lack of adequate and easily accessible processing tools. We report on an additive manufacturing platform to fabricate complex-shaped parts exhibiting bio-inspired heterogeneous microstructures with locally tunable texture, composition and properties and unprecedentedly high volume fractions of inorganic phase (up to 100%). The technology combines an aqueous-based slip casting process with magnetically-directed particle assembly to create programmed microstructural designs using anisotropic stiff platelets in a ceramic, metal or polymer functional matrix. Using quantitative tools to control the casting kinetics and the temporal pattern of the applied magnetic fields, we demonstrate that this robust approach can be exploited to design and fabricate heterogeneous composites with thus far inaccessible microstructures. Proof-of-concept examples include bulk composites with periodic patterns of micro-reinforcement orientation and tooth-like bilayer parts with intricate shapes displaying site-specific composition and texture.

Published
2016
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37. PeakForest: a multi-platform digital infrastructure for interoperable metabolite spectral data and metadata management

Author

Paulhe, Nils, Canlet, Cécile, Damont, Annelaure, Peyriga, Lindsay, Durand, Stéphanie, Deborde, Catherine, Alves, Sandra, Bernillon, Stephane, Berton, Thierry, Bir, Raphael, Bouville, Alyssa, Cahoreau, Edern, Centeno, Delphine, Costantino, Robin, Debrauwer, Laurent, Delabrière, Alexis, Duperier, Christophe, Emery, Sylvain, Flandin, Amelie, Hohenester, Ulli, Jacob, Daniel, Joly, Charlotte, Jousse, Cyril, Lagree, Marie, Lamari, Nadia, Lefebvre, Marie, Lopez-Piffet, Claire, Lyan, Bernard, Maucourt, Mickael, Migne, Carole, Olivier, Marie-Francoise, Rathahao-Paris, Estelle, Petriacq, Pierre, Pinelli, Julie, Roch, Léa, Roger, Pierrick, Roques, Simon, Tabet, Jean-Claude, Tremblay-Franco, Marie, Traïkia, Mounir, Warnet, Anna, Zhendre, Vanessa, Rolin, Dominique, Jourdan, Fabien, Thévenot, Etienne, Moing, Annick, Jamin, Emilien, Fenaille, François, Junot, Christophe, Pujos-Guillot, Estelle, and Giacomoni, Franck

Published
2022
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38. Clinical characteristics of chronic lymphocytic leukemia occurring in chornobyl cleanup workers

Author

Finch, Stuart C, Dyagil, Irina, Reiss, Robert F, Gudzenko, Nataliya, Babkina, Nataliya, Lyubarets, Tatiana, Bebeshko, Volodymyr, Romanenko, Anatoly, Chumak, Vadim V, Bouville, Andre, Hatch, Maureen, Little, Mark P, Bazyka, Dimitry, and Zablotska, Lydia B

Subjects
Biomedical and Clinical Sciences, Clinical Sciences, Cancer, Rare Diseases, Clinical Research, Aging, Prevention, Hematology, Lymphoma, Detection, screening and diagnosis, 4.1 Discovery and preclinical testing of markers and technologies, Adult, Aged, Chernobyl Nuclear Accident, Humans, Leukemia, Lymphocytic, Chronic, B-Cell, Leukemia, Radiation-Induced, Male, Middle Aged, Occupational Exposure, Radiation Dosage, chronic lymphocytic leukemia, Chornobyl, Chernobyl, radiation, cleanup worker, Cardiorespiratory Medicine and Haematology, Immunology, Cardiovascular medicine and haematology
Abstract

The recently demonstrated radiation-induction of chronic lymphocytic leukemia (CLL) raises the question as to whether the amount of radiation exposure influences any of the clinical characteristics of the disease. We evaluated the relationship between bone marrow radiation doses and clinical characteristics and survival of 79 CLL cases diagnosed during 1986-2006 in a cohort of 110 645 male workers who participated in the cleanup work of the Chornobyl nuclear accident in Ukraine in 1986. All diagnoses were confirmed by an independent International Hematology Panel. Patients were followed up to the date of death or end of follow-up on 31 October 2010. The median age at diagnosis was 57 years. Median bone marrow dose was 22.6 milligray (mGy) and was not associated with time between exposure and clinical diagnosis of CLL (latent period), age, peripheral blood lymphocyte count or clinical stage of disease in univariate and multivariate analyses. Latent period was significantly shorter among those older at first exposure, smokers and those with higher frequency of visits to the doctor prior to diagnosis. A significant increase in the risk of death with increasing radiation dose was observed (p = 0.03, hazard ratio = 2.38, 95% confidence interval: 1.11,5.08 comparing those with doses ≥22 mGy to doses

Published
2017

39. Self-Assembly of Faceted Particles Triggered by a Moving Ice Front

Author

Bouville, Florian, Maire, Eric, and Deville, Sylvain

Subjects
Condensed Matter - Materials Science, Condensed Matter - Soft Condensed Matter
Abstract

The possibility to align and organize faceted particles in the bulk offers intriguing possibilities for the design and discovery of materials and architectures exhibiting novel functional properties. The growth of ice crystals can be used to trigger the self-assembly of large, anisotropic particles and consequently to obtain three-dimensional porous materials of large dimensions in a limited amount of time. These mechanisms have not been explored so far due to the difficulty to experimentally investigate these systems. Here we elucidate the self-assembly mechanisms of faceted particles driven by ice growth by a combination of X-ray holotomography and discrete element modeling, providing insights into both the dynamics of self-assembly and their final packing. The encapsulation of particles is the result of a delicate balance between the force exerted by the percolating network of concentrated particles and the force exerted by the moving interface. We illustrate the benefits of such self-assembly for thermal management composite materials., Comment: 27 pages, 6 figures, 42 references

Published
2015
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40. Templated Grain Growth in Macroporous Materials

Author

Bouville, Florian, Portuguez, Etienne, Chang, Yunfei, Messing, Gary L., Stevenson, Adam J., Maire, Eric, Courtois, Loic, and Deville, Sylvain

Subjects
Condensed Matter - Materials Science
Abstract

We demonstrate a facile method to produce crystallographically textured, macroporous materials using a combination of modified ice templating and templated grain growth (TGG). The process is demonstrated on alumina and the lead-free piezoelectric material sodium potassium niobate. The method provides macroporous materials with aligned, lamellar ceramic walls which are made up of crystallographically aligned grains. Each method showed that the ceramic walls present a long-range order over the entire sample dimensions and have crystallographic texture as a result of the TGG process. We also present a modification of the March-Dollase equation to better characterize the overall texture of materials with textured but slightly misaligned walls. The controlled crystallographic and morphologic orientation at two different length scales demonstrated here can be the basis of multifunctional materials., Comment: 14 pages, 7 figures, 19 references

Published
2015
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41. Strong, Tough and Stiff Bioinspired Ceramics from Brittle Constituents

Author

Bouville, Florian, Maire, Eric, Meille, Sylvain, Van de Moortèle, Bertrand, Stevenson, Adam J., and Deville, Sylvain

Subjects
Condensed Matter - Materials Science
Abstract

High strength and high toughness are usually mutually exclusive in engineering materials. Improving the toughness of strong but brittle materials like ceramics thus relies on the introduction of a metallic or polymeric ductile phase to dissipate energy, which conversely decreases the strength, stiffness, and the ability to operate at high temperature. In many natural materials, toughness is achieved through a combination of multiple mechanisms operating at different length scales but such structures have been extremely difficult to replicate. Building upon such biological structures, we demonstrate a simple approach that yields bulk ceramics characterized by a unique combination of high strength (470 MPa), high toughness (22 MPa.m1/2), and high stiffness (290 GPa) without the assistance of a ductile phase. Because only mineral constituents were used, this material retains its mechanical properties at high temperature (600{\deg}C). The bioinspired, material-independent design presented here is a specific but relevant example of a strong, tough, and stiff material, in great need for structural, transportations, and energy-related applications., Comment: 27 pages, 4 figures, supplementary data, 47 references

Published
2015
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42. Engineered SiC materials for power technologies.

Author

Walter Schwarzenbach, S. Rouchier, G. Berre, R. Boulet, O. Ledoux, Enrica Cela, Alexis Drouin, A. Chapelle, S. Monnoye, H. Biard, K. Alassaad, L. Viravaux, N. Ben Mohamed, D. Radisson, G. Picun, G. Lavaitte, A. Bouville-Lallart, J. Roi, J. Widiez, K. Abadie, E. Rolland, F. Fournel, G. Gélineau, F. Mazen, A. Moulin, C. Moulin, D. Delprat, N. Daval, S. Odoul, P. Sandri, and Christophe Maleville

Published
2022
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44. Tough metal-ceramic composites with multifunctional nacre-like architecture

Author

Erik Poloni, Florian Bouville, Christopher H. Dreimol, Tobias P. Niebel, Thomas Weber, Andrea R. Biedermann, Ann M. Hirt, and André R. Studart

Subjects
Medicine, Science
Abstract

Abstract The brick-and-mortar architecture of biological nacre has inspired the development of synthetic composites with enhanced fracture toughness and multiple functionalities. While the use of metals as the “mortar” phase is an attractive option to maximize fracture toughness of bulk composites, non-mechanical functionalities potentially enabled by the presence of a metal in the structure remain relatively limited and unexplored. Using iron as the mortar phase, we develop and investigate nacre-like composites with high fracture toughness and stiffness combined with unique magnetic, electrical and thermal functionalities. Such metal-ceramic composites are prepared through the sol–gel deposition of iron-based coatings on alumina platelets and the magnetically-driven assembly of the pre-coated platelets into nacre-like architectures, followed by pressure-assisted densification at 1450 °C. With the help of state-of-the-art characterization techniques, we show that this processing route leads to lightweight inorganic structures that display outstanding fracture resistance, show noticeable magnetization and are amenable to fast induction heating. Materials with this set of properties might find use in transport, aerospace and robotic applications that require weight minimization combined with magnetic, electrical or thermal functionalities.

Published
2021
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45. Diffusion–convection impedance for a micro-band electrode under microfluidic conditions

Author

Claire Poujouly, Pedro Gonzalez-Losada, Rassen Boukraa, Martina Freisa, Jérémy Le Gall, David Bouville, Claude Deslouis, and Jean Gamby

Subjects
Channel-electrode, Microfluidics, Impedance, Diffusion–convection, Reduced frequency, Industrial electrochemistry, TP250-261, Chemistry, QD1-999
Abstract

Diffusion–convection impedance for a micro-band electrode placed in a Poiseuille flow was studied experimentally under microfluidic conditions. Electrochemical impedance spectroscopy (EIS) experiments performed with a fast electrochemical system show perfect agreement with a previously published quantitative analytical expression in the low frequency domain.

Published
2022
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46. Microfluidic Chip for the Electrochemical Detection of MicroRNAs: Methylene Blue Increasing the Specificity of the Biosensor

Author

Claire Poujouly, Jérémy Le Gall, Martina Freisa, Djamila Kechkeche, David Bouville, Jihed Khemir, Pedro Gonzalez-Losada, and Jean Gamby

Subjects
microfluidics, miRNA electrochemical detection, methylene blue (MB), microelectrodes, surface functionalization, Chemistry, QD1-999
Abstract

MicroRNAs (miRNAs) are biomarkers involved in biological processes that are released by cells and found in biological fluids such as blood. The development of nucleic acid-based biosensors has significantly increased in the past 10 years because the detection of such nucleic acids can easily be applied in the field of early diagnosis. These biosensors need to be sensitive, specific, and fast in order to be effective. This work introduces a newly-built electrochemical biosensor that enables a fast detection in 30 min and, as a result of its integration in microfluidics, presents a limit of detection as low as 1 aM. The litterature concerning the specificity of electrochemical biosensors includes several studies that report one base-mismatch, with the base-mismatch located in the middle of the strand. We report an electrochemical nucleic acid biosensor integrated into a microfluidic chip, allowing for a one-base-mismatch specificity independently from the location of the mismatch in the strand. This specificity was improved using a solution of methylene blue, making it possible to discriminate a partial hybridization from a complete and complementary hybridization.

Published
2022
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