Patent application number | Description | Published |
20080272418 | Semiconductor component comprising a buried mirror - A method for forming a buried mirror in a semiconductor component includes the steps of forming a structure comprising a semiconductor layer laid on an insulating layer covering a substrate; forming one or several openings in the semiconductor layer emerging at the surface of the insulating layer; eliminating a portion of the insulating layer, whereby a recess is formed; forming a second thin insulating layer against the wall of the recess; and forming a metal layer in the recess against the second insulating layer. | 11-06-2008 |
20090256224 | INTEGRATED CIRCUIT COMPRISING MIRRORS BURIED AT DIFFERENT DEPTHS - A semiconductor structure including a first active area under which is buried a first reflective layer and a least one second active area under which is buried a second reflective layer, wherein the upper surface of the second reflective layer is closer to the upper surface of the structure than the upper surface of the first reflective layer. | 10-15-2009 |
20110108939 | METHOD FOR FORMING A BACK-SIDE ILLUMINATED IMAGE SENSOR - A method for manufacturing a back-side illuminated image sensor, including the steps of: forming, inside and on top of an SOI-type silicon layer, components for trapping and transferring photogenerated carriers and isolation regions; forming a stack of interconnection levels on the silicon layer and attaching, on the interconnect stack, a semiconductor handle; removing the semiconductor support; forming, in the insulating layer and the silicon layer, trenches reaching the isolation regions; depositing a doped amorphous silicon layer, more heavily doped than the silicon layer, at least on the walls and the bottom of the trenches and having the amorphous silicon layer crystallize; and filling the trenches with a reflective material. | 05-12-2011 |
20120261670 | BACK-SIDE ILLUMINATED IMAGE SENSOR WITH A JUNCTION INSULATION - A method for forming a back-side illuminated image sensor, including the steps of: a) forming, from the front surface, doped polysilicon regions, of a conductivity type opposite to that of the substrate, extending in depth orthogonally to the front surface and emerging into the first layer; b) thinning the substrate from its rear surface to reach the polysilicon regions, while keeping a strip of the first layer; c) depositing, on the rear surface of the thinned substrate, a doped amorphous silicon layer, of a conductivity type opposite to that of the substrate; and d) annealing at a temperature capable of transforming the amorphous silicon layer into a crystallized layer. | 10-18-2012 |
20120261732 | METHOD FOR FORMING A BACK-SIDE ILLUMINATED IMAGE SENSOR - A method for forming a back-side illuminated image sensor from a semiconductor substrate, including the steps of: a) thinning the substrate from its rear surface; b) depositing, on the rear surface of the thinned substrate, an amorphous silicon layer of same conductivity type as the substrate but of higher doping level; and c) annealing at a temperature enabling to recrystallized the amorphous silicon to stabilize it. | 10-18-2012 |
20120261783 | BACK-SIDE ILLUMINATED IMAGE SENSOR PROVIDED WITH A TRANSPARENT ELECTRODE - A back-side illuminated image sensor formed from a thinned semiconductor substrate, wherein: a transparent conductive electrode, insulated from the substrate by an insulating layer, extends over the entire rear surface of the substrate; and conductive regions, insulated from the substrate by an insulating coating, extend perpendicularly from the front surface of the substrate to the electrode. | 10-18-2012 |
20120261784 | METHOD FOR FORMING A BACK-SIDE ILLUMINATED IMAGE SENSOR - A method for forming a back-side illuminated image sensor from a semiconductor substrate, including the steps of: a) forming, from the front surface of the substrate, areas of same conductivity type as the substrate but of higher doping level, extending deep under the front surface, these areas being bordered with insulating regions orthogonal to the front surface; b) thinning the substrate from the rear surface to the vicinity of these areas and all the way to the insulating regions; c) partially hollowing out the insulating regions on the rear to surface side; and d) performing a laser surface anneal of the rear surface of the substrate. | 10-18-2012 |
20130075870 | METHOD FOR PROTECTION OF A LAYER OF A VERTICAL STACK AND CORRESPONDING DEVICE - A device and corresponding fabrication method includes a vertical stack having an intermediate layer between a lower region and an upper region. The intermediate layer is extended by a protection layer. The vertical stack has a free lateral face on which the lower region, the upper region and the protection layer are exposed. | 03-28-2013 |
20130335666 | NANOPROJECTOR PANEL FORMED OF AN ARRAY OF LIQUID CRYSTAL CELLS - A nanoprojector panel formed of an array of cells, each cell including a liquid crystal layer between upper and lower transparent electrodes, a MOS control transistor being arranged above the upper electrode, each transistor being covered with at least three metallization levels. The transistor of each cell extends in a corner of the cell so that the transistors of an assembly of four adjacent cells are arranged in a central region of the assembly. The upper metallization level extends above the transistors of each the assembly of four adjacent cells. The panel includes, for each assembly of four adjacent cells, a first conductive ring surrounding the transistors, the first ring extending from the lower metallization level to the upper electrode of each cell, with an interposed insulating material. | 12-19-2013 |
20140217541 | BACK-SIDE ILLUMINATED IMAGE SENSOR WITH A JUNCTION INSULATION - A method for forming a back-side illuminated image sensor, including the steps of: a) forming, from the front surface, doped polysilicon regions, of a conductivity type opposite to that of the substrate, extending in depth orthogonally to the front surface and emerging into the first layer; b) thinning the substrate from its rear surface to reach the polysilicon regions, while keeping a strip of the first layer; c) depositing, on the rear surface of the thinned substrate, a doped amorphous silicon layer, of a conductivity type opposite to that of the substrate; and d) annealing at a temperature capable of transforming the amorphous silicon layer into a crystallized layer. | 08-07-2014 |