Abstract: Bipolar transistors and MOS transistors are formed in a common process. A semiconductor layer is arranged on an insulating layer. On a side of the bipolar transistors: an insulating region including the insulating layer is formed; openings are etched through the insulating region to delimit insulating walls; the openings are filled with first epitaxial portions; and the first epitaxial portions and a first region extending under the first epitaxial portions and under the insulating walls are doped. On the side of the bipolar transistors and on a side of the MOS transistors: gate structures are formed; second epitaxial portions are made; and the second epitaxial portions covering the first epitaxial portions are doped.

Abstract: A semiconductor nanolaser includes a rib formed by a stack of layers, in which stack central layers (33, 34, 35) forming an assembly of quantum wells are placed between a lower layer (32) of a first conductivity type and an upper layer (36) of a second conductivity type. Holes (42) are drilled right through the thickness of the rib, wherein the lower layer includes first extensions (38, 40) that extend laterally on either side of the rib, and that are coated with first metallizations (42, 44) that are located a distance away from the rib. The stack includes second extensions (45, 46) that extend longitudinally beyond said rib, and that are coated with second metallizations (47, 48).

Abstract: A photodiode produces photogenerated charges in response to exposure to light. An integration period collects the photogenerated charges. Collected photogenerated charges in excess of an overflow threshold are passed to an overflow sense node. Remaining collected photogenerated charges are passed to a sense node. A first signal representing the overflow photogenerated charges is read from the overflow sense node. A second signal representing the remaining photogenerated charges is read from the sense node.

Abstract: A global shutter image sensor of a back-illuminated type includes a semiconductor substrate and pixels. Each pixel includes a photosensitive area, a storage area, a readout area and areas for transferring charges between these different areas. The image sensor includes, for each pixel, a protector extending at least partly into the substrate from the back of the substrate to ensure that the storage area is protected against back illumination.

Abstract: An electronic device includes a support and a component in the form of an integrated circuit chip having a rear face mounted above a front face of the support and a front face opposite its rear face. A block is provided for at least partially encapsulating the component above the front face of the support. The device also includes at least one thermal dissipation member having a flexible sheet having at least two portions folded onto one another while forming at least one fold between them, these portions facing one another at least partly.

Abstract: An image sensor includes a first semiconductor substrate supporting a photodiode and a source region of a transfer transistor. A first interconnect level on the first semiconductor substrate includes an interconnection dielectric layer on the first semiconductor substrate and interconnect line layers over the interconnection dielectric layer. A second semiconductor substrate that supports readout transistors is mounted over the first semiconductor substrate and first interconnect level. The first interconnect level further includes a first doped semiconductor material electrical connection in physical and electrical contact with the source region in the first semiconductor substrate that passes through the interconnection dielectric layer and the interconnect line layers to electrically connect to at least one transistor of the readout transistors.

Abstract: A semiconductor substrate includes a photodiode region, a charge storage region electrically coupled to the photodiode region and a capacitive deep trench isolation (CDTI) structure including a conductive region positioned between the photodiode region and the charge storage region. A contact etch stop layer overlies the semiconductor substrate and a premetallization dielectric layer overlies the contact etch stop layer. A first trench, filled with a metal material, extends through the premetallization dielectric layer and bottoms out at or in the contact etch stop layer. A second trench, also filled with the metal material, extends through the premetallization dielectric layer and the contact etch stop layer and bottoms out at or in the conductive region of the CDTI structure. The metal filled first trench forms an optical shield between the photodiode region and the charge storage region. The metal filled second trench forms a contact for biasing the CDTI structure.

Abstract: An integrated image sensor may include adjacent pixels, with each pixel including an active semiconductor region including a photodiode, an antireflection layer disposed above the photodiode, a dielectric region disposed above the antireflection layer, an optical filter disposed above the dielectric region, and a diffraction grating disposed in the antireflection layer. The diffraction grating includes an array of pads.

Abstract: An image sensor chip includes a semiconductor layer intended to receive illumination on a back face and comprising a matrix of pixels on a front face. An interconnection structure is arranged on the front face and a carrier is attached to the interconnection structure with a first face of the carrier facing the front face. An annular trench, arranged on a perimeter of the image sensor chip, extends from a second face of the carrier through an entire thickness of the carrier and into the interconnection structure. A via opening, arranged within the annual trench, extends from the second face of the carrier through the entire thickness of the carrier to reach a metal portion of the interconnection structure. The via opening an annual trench are lined with an insulating layer. The via opening include a metal conductor making an electrical connection to the metal portion.

Abstract: A heat-transferring device is formed by a stack that includes at least one heat-conducting layer and at least one heat-absorbing layer. The at least one heat-conducting layer has at least one heat-collecting section placed facing a heat source and at least one heat-evacuating section placed facing a heat sink. The at least one heat-absorbing layer includes a phase-change material. One face of the at least one heat-absorbing layer is adjoined to at least one portion of at least one face of the heat-conducting layer.

Abstract: An integrated circuit includes a high-voltage MOS (HV) transistor and a capacitor supported by a semiconductor substrate. A gate stack of the HV transistor includes a first insulating layer over the semiconductor layer and a gate electrode formed from a first polysilicon. The capacitor includes a first electrode made of the first polysilicon and a second electrode made of a second polysilicon and at least partly resting over the first electrode. A first polysilicon layer deposited over the semiconductor substrate is patterned to form the first polysilicon of the gate electrode and first electrode, respectively. A second polysilicon layer deposited over the semiconductor substrate is patterned to form the second polysilicon of the second electrode. Silicon oxide spacers laterally border the second electrode and the gate stack of the HV transistor. Silicon nitride spacers border the silicon oxide spacers.

Abstract: The invention relates to a method for manufacturing a transistor comprising the preparation of a stack of layers of the semiconductor on insulator type comprising at least one substrate on which an insulating layer and an initial semiconductor layer are successively disposed. The method includes the formation of at least one oxide pad extending from a top face of the insulating layer, the formation of an additional layer made from semiconductor material covering the oxide pad and intended to form a channel for the transistor, the formation of a gate stack above the oxide pad, and the formation of a source and drain on either side of the gate stack.

Abstract: A detector of an event includes an electrical energy generator formed by a flexible piezoelectric element with a weight fastened to the flexible piezoelectric element that is biased with the weight in a position with the piezoelectric element flexed. In response to detection of the event, a trigger releases the weight so as to cause a vibration of the piezoelectric element. This vibration is converted by the flexible piezoelectric element into electrical energy. An electronic system is power by the electrical energy and is operable to generate an electrical signal indicative of the detected event.

Abstract: A system includes a hot source, a cold source, and a device thermally coupled between the hot source and the cold source. The device includes a thermal-mechanical transducer and a mechanical-electrical transducer. The thermal-mechanical transducer includes a band of bimetallic strips linked mechanically together by their longitudinal ends. The band partially suspended over a portion of a substrate. Each bimetallic strip has a first stable state having a first curvature and a second stable state having a second curvature opposite the first curvature, and adjacent bimetallic strips have opposite curvature.

Abstract: A semiconductor device includes a first semiconductor substrate with a first transistor therein. The first transistor includes a first source-drain formed by a doped region in the first semiconductor substrate. An intermediary insulating layer is formed on and above the first semiconductor substrate. A second semiconductor substrate is formed on and above the intermediary insulating layer. A second transistor is formed in the second semiconductor substrate, and includes a second source-drain formed by a doped region in the second semiconductor substrate. A trench is formed in the second semiconductor substrate and in contact with the doped region for the second semiconductor substrate. The trench has a thickness equal to that of the second semiconductor substrate. Metal wiring extends from a contact with the doped region for the first source-drain, through the intermediary insulating layer and the trench, to make electrical contact with the doped region for the second source-drain.

Abstract: A method of manufacturing a heat pipe, including the steps of: forming in a substrate a cylindrical opening provided with a plurality of ring-shaped recessed radially extending around a central axis of the opening; arranging in the recesses separate ring-shaped strips made of a material catalyzing the growth of carbon nanotubes; and growing carbon nanotubes in the opening from said ring-shaped strips.

Abstract: A MOS transistor having a gate insulator including a dielectric of high permittivity and a conductive layer including a TiN layer, wherein the nitrogen composition in the TiN layer is sub-stoichiometric in its lower portion and progressively increases to a stoichiometric composition in its upper portion.

Abstract: An integrated circuit chip includes an interconnection stack with a cavity formed therein. The cavity extends through one or more interconnection levels of the stack. A material at least partially fills the cavity. The fill material has a selectivity to polishing and/or to etching different by more than 10% from a selectivity to polishing and/or to etching of a material forming an insulator of the interconnection stack.

Abstract: A back-side illuminated image sensor includes memory regions formed in a semiconductor wafer. Each memory region is located between two opaque walls which extend into the semiconductor wafer. An opaque screen is arranged at the rear surface of the memory region and in electrical contact with the opaque walls.

Abstract: A first semiconductor substrate layer supports a first transistor including a first source-drain formed by a doped region of the substrate layer. A second semiconductor substrate layer supports a second transistor including a second source-drain formed by a doped region of the substrate layer. The second semiconductor substrate layer is stacked over the first semiconductor substrate layer and separated therefrom by an insulating layer. A metal wiring extends from an electrical contact with the doped region for the first source-drain, through the insulating layer and passing through an electrical isolation structure in the second semiconductor substrate layer to make an electrical contact with the doped region for the second source-drain. The electrical isolation structure is formed by one of a trench isolation or the doped region of the second source-drain itself. The isolation structure has a thickness equal to a thickness of the second semiconductor substrate layer.