Abstract: A method for treating a region of an optoelectronic device (Pix) further including a substrate adjacent to the region to be treated. The optoelectronic device includes, in the region to be treated, programmable elements configured to be modified when they are exposed to a laser beam. The method includes the exposure of at least one of the programmable elements to the laser beam focused through the substrate.

Abstract: The manufacture of an optoelectronic device includes the formation of wire-like shaped light-emitting diodes and the formation of spacing walls transparent to the light radiation originating from the diodes. The lateral sidewalls of each diode are surrounded by at least one of the spacing walls. Light confinement walls directly cover the lateral sidewalls of the spacing walls by being in contact with the latter. The radiation originating from each diode and directed in the direction of the adjacent diodes is blocked by the confinement wall. The upper borders of the diodes are covered by the light confinement material so as to ensure a light extraction by the rear face of the optoelectronic device. An optoelectronic device is also described as such.

Abstract: An optoelectronic device including an optoelectronic circuit including light-emitting diodes, thin-film transistors, and a stack of electrically-insulating layers, said stack being located between the light-emitting diodes, and the transistors stack further including conductive elements, between and through the insulating layers, the conductive elements connecting at least some of the transistors to the light-emitting diodes The device further includes a support having a surface, the support being flexible and/or the surface being curved and non-planar, the optoelectronic circuit being connected to the surface on the side of the thin-film transistors.

Abstract: An optoelectronic device including a support, at least a first conductive layer covering the support, display pixels including first and second opposite surfaces, bonded to the first conductive layer, each pixel including an electronic circuit including the first surface and a third surface opposite to the first surface, the first surface being bonded to the first conductive layer, and an optoelectronic circuit bonded to the third surface and including at least two light-emitting diodes, at least one of the electrodes of each light-emitting diode being connected to the electronic circuit by the third surface, the optoelectronic circuit further comprising photoluminescent blocks covering the light-emitting diodes and conductive or semiconductor walls surrounding the photoluminescent blocks, and at least one second conductive layer electrically coupled to at least one of the pixels.

Abstract: An optoelectronic device including a support, at least hydrophilic photoluminescent blocks including hydrophilic photoluminescent particles covering first areas of the support and hydrophobic photoluminescent blocks including hydrophobic photoluminescent particles covering second areas of the support, the hydrophilic photoluminescent blocks being in contact with a hydrophilic material in the first areas and the hydrophobic photoluminescent blocks being in contact with a hydrophobic material in the second areas.

Abstract: An optoelectronic device, including: light-emitting sources, each light-emitting source being capable of emitting a first radiation at a first wavelength; photoluminescent blocks distributed into first photo-luminescent blocks capable of converting by optical pumping the first radiation into a second radiation at a second wavelength and second photoluminescent blocks capable of converting by optical pumping the first radiation into a third radiation at a third wavelength; and for each photoluminescent block, an optical coupler including a first photonic crystal at least partially surrounding the photoluminescent block and covering, with the photo-luminescent block, one of the light-emitting sources next to the photoluminescent block, the optical coupler being capable of modifying the propagation direction of rays of the first radiation emitted by the light-emitting source to redirect the rays towards the photoluminescent block.

Abstract: An optoelectronic device including light-emitting components, each light-emitting component being adapted to emit a first radiation at a first wavelength, and photoluminescent blocks, each photoluminescent block facing at least one light-emitting component and comprising a single quantum well or multiple quantum wells, photoluminescent blocks being divided into first photoluminescent blocks adapted to convert by optical pumping the first radiation into a second radiation at a second wavelength, second photoluminescent blocks adapted to convert by optical pumping the first radiation into a third radiation at a third wavelength and third photoluminescent blocks adapted to convert by optical pumping the first radiation into a fourth radiation at a fourth wavelength.

Abstract: A method for transferring electroluminescent structures onto a face, referred to as the accommodating face, of an accommodating substrate. The accommodating face is moreover provided with interconnections intended to individually address each of the structures. The electroluminescent structures are initially formed on a supporting substrate and are separated by tracks. It is then proposed in the present invention to form reflective walls, vertically above the tracks, which comprise a supporting polymer (the second polymer) supporting a metal film on its sides. Such an arrangement of reflective walls makes it possible to reduce the stresses exerted on the electroluminescent structures during the transfer method according to the present invention. Moreover, the reflective walls, within the meaning of the present invention, may be produced on all the electroluminescent structures resting on a supporting substrate.

Abstract: An optoelectronic device including a substrate having opposite first and second surfaces; insulation trenches extending through the substrate, surrounding portions of the substrate and electrically insulating the portions from each other, each insulation trench being filled with at least one electrically insulating block and a gaseous volume or being filled with an electrically conductive element electrically isolated from the substrate; at least one light-emitting diode resting on the first surface for each portion of the substrate, the light-emitting diodes comprising wired, conical, or frustoconical semiconductor elements; an electrode layer covering at least one of the light-emitting diodes and a conductive layer overlying the electrode layer around the light-emitting diodes; and a layer encapsulating the light-emitting diodes and covering the entire first surface.

Abstract: An optoelectronic device including: a first circuit including a substrate having first and second opposite faces, the first circuit having display pixels, each display pixel having, on the side of the first face, a first light-emitting diode having a first active region adapted to emit a first radiation and, extending from the second face, a second light-emitting diode having a second active region adapted to emit a second radiation, the surface area, viewed from a direction orthogonal to the first face, of the first active region being at least twice as big as the surface area, viewed from the direction, of the second active region; and a second circuit bonded to the first circuit on the side of the first light-emitting diode and electrically linked to the first and second light-emitting diodes.

Abstract: A method of manufacturing an optoelectronic device, including the steps of: forming, on a first surface of a first including assemblies of electronic components, a stack of insulating layers and of conductive tracks; forming, on another wafer, light-emitting diodes each comprising ends; forming a metal layer on at least a portion of the surface of the first wafer and another metal layer on at least a portion of the surface of the second wafer, the other metal layer being electrically coupled to the end of each light-emitting diode; placing into contact the metal layers; forming an insulated conductive via connecting another surface of the wafer to a conductive track; and forming insulated conductive trenches surrounding diodes.

Abstract: A device configured for a treatment with a laser, including a support transparent for the laser and at least one optoelectronic circuit including at least one optoelectronic component having a three-dimensional semiconductor element covered with an active layer, the three-dimensional semiconductor element including a base bonded to the support, the device including a region absorbing for the laser resting on the support and surrounding the base.

Abstract: A device configured for a laser treatment including a substrate transparent for the laser and objects, each object being bonded to the substrate via a photonic crystal.

Abstract: optoelectronic circuit intended to receive a variable voltage containing an alternation of rising and falling phases. The optoelectronic circuit includes light-emitting diodes and a switching device capable of allowing or of interrupting the flowing of a current through each light-emitting diode. Each light-emitting diode is covered with a photoluminescent layer. The photoluminescent layer covering at least one of the light-emitting diodes includes at least one first luminophore having a first decay constant and at least one second luminophore having a second decay constant different from the first decay constant.

Abstract: A device configured for a laser treatment, including a support and objects, each attached to the support via a region absorbing for the laser, the support comprising a system for optically guiding (42, 44, 50, 52) the laser towards at least a plurality of said absorbing regions.

Abstract: An optoelectronic device including: a three-dimensional semiconductor element mostly made of a first chemical element and of a second chemical element; an active area at least partially covering the lateral walls of the three-dimensional semiconductor element and including a stack of at least a first layer mostly made of the first and second chemical elements, and of at least a second layer mostly made of the first and second chemical elements and of a third chemical element; a third layer covering the active area, the third layer being mostly made of the first, second, and third chemical elements and of a fourth chemical element, the mass proportion of the third and fourth chemical elements of the third layer increasing or decreasing as the distance to the substrate increases; and a fourth layer, mostly made of the first and second chemical elements, covering the third layer.

Abstract: A device including a display screen including display pixels arranged in rows and in columns, including a first row and a first column. The device further includes a display screen control circuit configured to, in a first mode, start the display of a first image on the first row and on the first column and, in a second mode, start the display of a second image on one of the rows different from the first row and/or on one of the columns different from the first column.

Abstract: An optoelectronic device having a substrate and a plurality of sets of light-emitting diodes where each set includes a plurality of light-emitting diodes, a first lower electrode, a second upper electrode, an electronic component of an electronic circuit formed in a first portion of the substrate, on the side of the face of the substrate that does not bear the light-emitting diodes, and a first conductive means formed through the first portion and electrically connecting a first terminal of the electronic component to one amongst the first and second electrodes. The first conductive means of a given set is electrically-insulated from the first conductive means of the other sets.

Abstract: A method of protecting optoelectronic devices against electrostatic discharges, each optoelectronic device comprising an optoelectronic circuit comprising at least one optoelectronic component from among a light-emitting diode or a photodiode.

Abstract: An emitting device comprising a first light emitter adapted to emit a first radiation, and a second light emitter adapted to emit a second radiation different from the first radiation, the first light emitter comprising a first semiconducting structure and a first radiation converter, the second light emitter comprising a second semiconducting structure and a second radiation converter, each semiconducting structure comprising a semiconducting layer adapted to emit a third radiation, each radiation converter comprising a set of particles able to convert the third radiation into the first or second radiation, the particles of the first radiation converter being attached to a surface by a bulk of photosensitive resin and the particles of the second radiation converter being attached to a surface by grafting.