Abstract: At least one bipolar transistor and at least one variable capacitance diode are jointly produced by a method on a common substrate.

Abstract: The disclosure relates to integrated circuits and methods including one or more rows of transistors. In an embodiment, an integrated circuit includes a row of bipolar transistors including a plurality of first conduction regions, a second conduction region, and a common base between the first conduction regions and the second conduction region. An insulating trench is in contact with each bipolar transistor of the row of bipolar transistors. A conductive layer is on the insulating trench and the common base between the first conduction regions. A spacer layer is between the conductive layer and the first conduction regions.

Abstract: A method for manufacturing an electronic device includes locally implanting ionic species into a first region of a silicon nitride layer and into a first region of an electrically insulating layer located under the first region of the silicon nitride layer. A second region of the silicon nitride layer and a region of the electrically insulating layer located under the second region of the silicon nitride layer are protected from the implantation. The electrically insulating layer is disposed between a semi-conducting substrate and the silicon nitride layer. At least one trench is formed extending into the semi-conducting substrate through the silicon nitride layer and the electrically insulating layer. The trench separates the first region from the second region of the electrically insulating layer. The electrically insulating layer is selectively etched, and the etch rate of the electrically insulating layer in the first region is greater than the etch rate in the second region.

Abstract: The present description concerns a ROM including at least one first rewritable memory cell.

Abstract: An optoelectronic device is manufactured by an epitaxial growth, on each first layer of many first layers spaced apart from each other on a first support, wherein the first is made of a first semiconductor material, of a second layer made of a second semiconductor material. A further epitaxial growth is made on each second layer of a stack of semiconductor layers. Each stack includes a third layer made of a third semiconductor material in physical contact with the second layer. Each stack is then separated from the first layer by removing the second layer using an etching that is selective simultaneously over both the first and third semiconductor materials. Each stack is then transferred onto a second support. Each of the first and third semiconductor materials is one of a III-V compound or a II-VI compound.

Abstract: The present description relates to a method of manufacturing an end of an interconnection structure of an integrated circuit, the method including: providing an integrated circuit including an interconnection structure including copper interconnection elements at least partly extending through an insulating layer and flush with a first surface of said interconnection structure; forming a protection layer on the first surface of the interconnection structure, said protection layer including a material adapted to protecting the copper of the interconnection elements; forming a passivation layer on the protection layer, the passivation layer having a first thickness; and forming a first opening in the passivation layer across a second thickness smaller than the first thickness, to keep a residual passivation layer at the bottom of the first opening.

Abstract: An orthomode junction for separating and/or combining orthogonally-polarized radiofrequency wave signals, comprises a body which has a main cavity forming a main waveguide, which has a blind end, and auxiliary cavities forming auxiliary waveguides, which communicate laterally with the main cavity in the vicinity of the blind end thereof, and a deflection insert situated at the blind end of the main cavity and facing the auxiliary cavities, the deflection insert having different shapes on the side of the auxiliary cavities respectively.

Abstract: The present description concerns a manufacturing method comprising the following steps: providing a silicon substrate having a via penetrating into the substrate from its front surface and comprising a silicon conductive core and a silicon oxide insulating sheath; etching the substrate from its rear surface, selectively over the sheath so that a portion of said at least one via protrudes from the rear surface; depositing a silicon oxide insulating layer on the rear surface; polishing the insulating layer to expose the core while leaving in place a portion of the thickness of the insulating layer; and forming a conductive electrode in contact with the core.

Abstract: A device including a transistor is fabricated by forming a first part of a first region of the transistor through the implantation of dopants through a first opening. The second region of the transistor is then formed in the first opening by epitaxy.

Abstract: The present disclosure concerns a phase-change memory manufacturing method and a phase-change memory device. The method includes forming a first insulating layer in cavities located vertically in line with strips of phase-change material, and anisotropically etching the portions of the first insulating layer located at the bottom of the cavities; and a phase-change memory device including a first insulating layer against lateral walls of cavities located vertically in line with strips of phase-change material.

Abstract: A bipolar transistor includes a collector region having a first doped portion located in a substrate and a second doped portion covering and in contact with an area of the first doped portion. The collector region has a doping profile having a peak in the first portion and a decrease from this peak up to in the second portion.

Abstract: The present description concerns a manufacturing method comprising, for each photodetector of an array of photodetectors of a light sensor, a use of a mask obtained by directed self-assembly of a block copolymer to form, by a first etch step, at least one first structure on the side of a first surface of the photodetector intended to receive light.

Abstract: The present disclosure is directed to conductive structures that may be utilized in a radio-frequency (RF) switch. The embodiments of the conductive structures of the present disclosure are formed to balance the “on” resistance (Ron) and the “off” capacitance (Coff) such that the Ron·Coff value is optimized such that the conductive structures are relatively efficient as compared to conventional conductive structures within conventional RF switches. For example, the conductive structures include various metallization layers that are stacked on each other and spaced apart in a selected manner to balance the Ron and the Coff as to optimize the Ron·Coff figure of merit as a lower Ron·Coff is preferred.

Abstract: A diode and a transistor are connected in parallel. The transistor is located on a first doped region forming a PN junction of the diode with a second doped region located under the first region. The circuit functions as an ionizing radiation detection cell by generating a current through the PN junction which changes by a voltage generated across the transistor. This change in voltage is compared to a threshold to detect the ionizing radiation.

Abstract: An image sensor is includes a plurality of pixels. Each of the pixels includes a silicon photoconversion region and a material that at least partially surrounds the photoconversion region. The material has a refraction index smaller than the refraction index of silicon, and the interface between the photoconversion region of the pixel and the material is configured so that at least one ray reaching the photoconversion region of the pixel undergoes a total reflection or a plurality of successive total reflections at the interface.

Abstract: A method for manufacturing an electronic chip includes providing a semiconductor layer located on an insulator covering a semiconductor substrate. First and second portions of the semiconductor layer are oxidized up to the insulator. Stresses are generated in third portions of the semiconductor layer, and each of the third portions extend between two portions of the semiconductor layer that are oxidized. Cavities are formed which extend at least to the substrate through the second portions and the insulator. Bipolar transistors are formed in at least part of the cavities and first field effect transistors are formed in and on the third portions. Phase change memory points are coupled to the bipolar transistors.

Abstract: An integrated circuit includes at least one silicon region and at least one metal pillar in contact with the at least one silicon region at an ohmic coupling region. The at least one metal pillar is formed by: depositing a layer of titanium on the at least one silicon region; depositing atomic layers of titanium nitride on the layer of titanium; and annealing at a temperature of between 715° C. and 815° C. for a period of between 5 seconds and 30 seconds. This forms a titanium silicide for the ohmic coupling region in a volume having the appearance of a spherical cap or segment.

Abstract: A vertical photodiode includes an active area. The contacting pads for the diode terminals are laterally shifted away from the active area so as to not be located above or below the active area. The active area is formed in a layer of semiconductor material by a lower portion of a germanium area that is intrinsic and an upper portion of the germanium area that is doped with a first conductivity type. The vertical photodiode is optically coupled to a waveguide formed in the layer of semiconductor material.

Abstract: An imaging device includes an array of photosensors. A film of semiconductor nanoparticles is common to the photosensors of the array. The nanoparticles are configured to be excited by light with wavelengths in a range from 280 to 1500 nanometers. Each photosensor includes a top electrode and a bottom electrode positioned on opposite sides of the film of semiconductor nanoparticles. At least some of the photosensors further include a filter configured to transmit light with wavelengths in a range from 280 to 400 nanometers, and to at least partially filter out light with wavelengths greater than 400 nanometers from reaching the photosensor. A transistor level is electrically coupled to the top and bottom electrodes of the photosensors.

Abstract: A photodiode is formed in a semiconductor substrate having a first surface and a second surface. The semiconductor substrate includes a first N-type semiconductor region formed by epitaxial growth and a second N-type semiconductor region (that is more heavily doped than the first region) extending into the first N-type semiconductor region from the first surface. The dopant concentration of the first N-type semiconductor region gradually increases between the second surface and the first surface of the semiconductor substrate. An implanted heavily P-type doped region is formed in the second N-type semiconductor region at the first surface.