Abstract: The present invention is in the field of surfactants to extract a platinum group metal or gold, in particular palladium, from organic compositions. In particular, the invention concerns the use of surfactants to back-extract a platinum group metal or gold, in particular palladium, from organic compositions further comprising an extractant of said platinum group metal or gold, in particular palladium from an aqueous solution.

Abstract: A process for making at least one porous area (ZP) of a microelectronic structure in at least one part of an conducting active layer (6), the active layer (6) forming a front face of a stack, the stack comprising a back face (2) of conducting material and an insulating layer (4) interposed between the active layer (6) and the back face (2), said process comprising the steps of: a) making at least one contact pad (14) between the back face (2) and the active layer (6) through the insulation layer (2), b) placing the stack into an electrochemical bath, c) applying an electrical current between the back face (2) and the active layer (6) through the contact pad (14) causing porosification of an area (ZP) of the active layer (6) in the vicinity of the contact pad (14), d) forming the microelectronic structure.

Abstract: There is provided a Nuclear Magnetic Resonance (NMR) measurement cell for use with a solution enabling the introduction of a gas into said solution. The measurement cell includes at least a detection volume designed to be installed in a static magnetic field of an NMR spectrometer, and includes in said detection volume, a gas introduction zone, a measurement chamber for the solution at a distance from the gas introduction zone and a network of conduits for the solution formed to set up fluid communication between the gas introduction zone and the measurement chamber. The gas introduction zone includes at least one gas inlet in the network of conduits, to generate bubbles in the gas introduction zone only. There is also provided a method of manufacturing such a measurement cell and a measurement assembly including such a measurement cell.

Abstract: A method for preparing oxyborane compounds of formula (I): using carbon dioxide, and the use of the oxyborane compounds obtained in this way for preparing methane derivatives, in particular oxygenated, halogenated or amino derivatives of methane. The methane derivatives obtained in this way can then be used in the production of vitamins, pharmaceutical products, glues, acrylic fibers and synthetic leathers, pesticides, and fertilizers, for example. Also provided is a method for producing vitamins, pharmaceutical products, glues, acrylic fibers, synthetic leathers, pesticides, and fertilizers, for example, including a step of preparing methane derivatives, in particular oxygenated, halogenated or amino derivatives of methane, from oxyborane compounds obtained by the method according to the invention. Further provided is a method of preparing labelled oxyborane compounds and the use of same.

Abstract: Method for producing a substrate comprising at least one getter material arranged on the walls of at least one blind hole, comprising at least the steps of: etching the blind hole through a first face of the substrate, depositing a continuous layer of getter material on the whole of the first face of the substrate and at least on the side walls of the blind hole, etching part of the layer of getter material located on the first face of the substrate such that said first face of the substrate is no longer covered by the getter material, in which the step of etching part of the layer of getter material comprises the implementation of an etching by ion beam machining, or chemical-mechanical planarization or polishing.

Abstract: The invention relates to a device for mass detection of particles in a fluid medium, including an electromechanical oscillator (7), excitation means (9) fitted so as to cause the said oscillator to vibrate, a fluid supply circuit (5), and a fluid system (11) incorporated in the said oscillator, where the said fluid system (11) is in fluid communication with the fluid supply circuit (5), where the said fluid system (11) includes at least one trapping site (21) configured to trap a particle of interest according to the size of the said particle of interest.

Abstract: An in-plane MEMS or NEMS detection device for measuring displacements directed along a direction including a seismic mass suspended with respect to a substrate, the seismic mass being pivotable about an axis perpendicular to the plane of the substrate, at least one piezoresistive strain gauge mechanically connected to the seismic mass and the substrate, wherein the piezoresistive gauge has a thickness lower than that of the seismic mass, and wherein the axis of the piezoresistive strain gauge is orthogonal to the plane containing the pivot axis and the center of gravity of the seismic mass and the plane is orthogonal to the direction of the displacements to be measured.

Abstract: The invention relates, in particular, to an instrument for measuring length, comprising an inductive sensor comprising an elongate body and a tip that is movable along a longitudinal axis. The body contains windings and defines a first cavity receiving a magnetic core. The instrument further comprises a casing which extends the body along the longitudinal axis, and which defines, together with the body, a second sealed cavity containing the tip. The capacity of the casing to resiliently deform along the longitudinal axis is greater than the capacity of said casing to resiliently deform along axes that are orthogonal to said longitudinal axis.

Abstract: Coordination complexes of at least one metal element with at least one aromatic monomer are provided. The at least one aromatic monomer may comprise at least one aromatic ring, which ring comprising at least one ethylenic group, at least one hydroxide group —OH, at least one oxime group and salts thereof. The metal element may be in the form of a metal alkoxide.

Abstract: An electrochemical cell comprises an inlet and an outlet for an electrolyte flow, and two unipolar electrodes. Each electrode comprises a structure with a network of through-passages, surrounded by a solid frame. The electrolyte enters via inlets, circulates via the passages of the electrodes, passes through the space between the electrodes and leaves via an outlet. The structure and the frame are based on carbon.

Abstract: A method for producing an electro-mechanical microsystem including movable mechanical parts, said method including a phase of releasing at least one movable mechanical part, wherein the releasing phase includes the following steps: formation of at least one porous zone in a first wafer of a semiconductor material; formation of at least a pattern of a material that makes at least one movable mechanical part on a front face of the first wafer and at least a partial encapsulation of the pattern in a sacrificial layer; release of the movable mechanical part through a rear face of the first wafer throughout the porous zone, using a solvent of the sacrificial layer.

Abstract: A method for producing at least one deformable membrane micropump including a first substrate and a second substrate assembled together, the first substrate including at least one cavity and the second substrate including at least one deformable membrane arranged facing the cavity. In the method: the cavity is produced in the first substrate; then the first and second substrates are assembled together; then the deformable membrane is produced in the second substrate.

Abstract: The invention relates to an imaging system and an associated device for detecting a sample (4). The imaging system comprises a matrix (24) of photosensors (26), a first lamina (28) disposed opposite the matrix (24) of photosensors defining a face (28A) for supporting the sample, and a set (30) of optical elements, disposed between the matrix (24) of photosensors and the first lamina (28). Each microlens (34) is disposed above a photosensor (26) of the matrix (24) of photosensors. The set (30) of optical elements comprises a matrix (32) of microlenses (34). The set (30) of optical elements comprises an optical medium (36) disposed between the matrix (32) of microlenses and the first lamina (28), the refractive index of the optical medium (36) being substantially between 1 and the refractive index of the microlenses (34).

Abstract: The magnetic device comprises a magnetic device comprising a magnetoresistive tunnel junction (100), itself comprising: a reference magnetic layer (120) having magnetization in a direction that is fixed; a storage magnetic layer (110) having magnetization in a direction that is variable; and an intermediate layer (130) acting as a tunnel barrier that is essentially semiconductor or electrically insulating and that separates the reference magnetic layer (120) from the storage magnetic layer (110). The potential profile of the intermediate layer (130) is asymmetrical across the thickness of said layer (130) so as to produce a current response that is asymmetrical as a function of the applied voltage. The device is applicable to magnetic random access memories.