Abstract: A method for manufacturing a fin MOS transistor from an SOI-type structure including a semiconductor layer on a silicon oxide layer coating a semiconductor support, this method including the steps of: a) forming, from the surface of the semiconductor layer, at least one trench delimiting at least one fin in the semiconductor layer and extending all the way to the surface of the semiconductor support; b) etching the sides of a portion of the silicon oxide layer located under the fin to form at least one recess under the fin; and c) filling the recess with a material selectively etchable over silicon oxide.

Abstract: Method to strain a channel zone of a transistor of the semiconductor on insulator type transistor that makes use of an SMT stress memorisation technique in which regions located under the insulation layer of the substrate (FIG. 6) are amorphised, before the transistor gate is made.

Abstract: A MOS transistor including, above a gate insulator, a conductive gate stack having a height, a length, and a width, this stack having a lower portion close to the gate insulator and an upper portion, wherein the stack has a first length in its lower portion, and a second length shorter than the first length in its upper portion.

Abstract: A method for producing a microelectronic device provided with different strained areas in the superficial layer of a semi-conductor on insulator type substrate comprising amorphizing a region of said superficial layer and then a lateral recrystallization of said region from crystalline areas adjoining this region (FIG. 1E).

Abstract: A method includes making a gate stack on the surface of an active zone, including depositing a first dielectric layer; depositing a gate conductive layer; depositing a first metal layer; depositing a second metal layer; depositing a second dielectric layer; partially etching the gate stack for the formation of a gate zone on the active zone; making insulating spacers on either side of the gate zone on the active zone; making source and drain electrodes zones; making silicidation zones on the surface of the source and drain zones; etching, in the gate zone on the active zone, the second dielectric layer and the second metal layer with stopping on the first metal layer, so as to form a cavity between the insulating spacers; making a protective plug at the surface of the first metal layer of the gate zone on the active zone, where the protective plug fills the cavity.

Abstract: A MOS transistor has a gate insulator layer that is made of a material of high dielectric constant deposited on a substrate. The gate insulator layer extends, with a constant thickness, under and beyond a gate stack. Spacers of low dielectric constant are formed on either side of the gate stack and vertically separated from the substrate by the extension of the gate insulator layer beyond the sides of the gate stack. The spacers of low dielectric constant are preferably air spacers.

Abstract: A method for manufacturing a transistor includes forming a stack of semiconductor on insulator type layers including at least one substrate, surmounted by a first insulating layer and an active layer to form a channel for the transistor; forming a gate stack on the active layer; producing a source and a drain including forming, on either side of the gate stack, cavities by at least one step of etching the active layer, the first insulating layer, and part of the substrate selectively to the gate stack to remove the active layer, the first insulating layer, and a portion of the substrate outside regions situated below the gate stack; forming a second insulating layer on the bared surfaces of the substrate, to form a continuous insulating layer with the first insulating layer; baring of the lateral ends of the channel; and the filling of the cavities by epitaxy.

Abstract: A method is provided for producing a semiconductor layer having at least two different thicknesses from a stack of the semiconductor on insulator type including at least one substrate on which an insulating layer and a first semiconductor layer are successively disposed, the method including etching the first layer so that said layer is continuous and includes at least one first region having a thickness less than that of at least one second region; oxidizing the first layer to form an electrically insulating oxide film on a surface thereof so that, in the first region, the oxide film extends as far as the insulating layer; partly removing the oxide film to bare the first layer outside the first region; forming a second semiconductor layer on the stack, to form, with the first layer, a third continuous semiconductor layer having a different thickness than that of the first and second regions.

Abstract: A method is provided for producing a semiconductor layer having at least two different thicknesses from a stack of the semiconductor on insulator type including at least one substrate on which an insulating layer and a first semiconductor layer are successively disposed, the method including etching the first layer so that said layer is continuous and includes at least one first region having a thickness less than that of at least one second region; oxidizing the first layer to form an electrically insulating oxide film on a surface thereof so that, in the first region, the oxide film extends as far as the insulating layer; partly removing the oxide film to bare the first layer outside the first region; forming a second semiconductor layer on the stack, to form, with the first layer, a third continuous semiconductor layer having a different thickness than that of the first and second regions.

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: The substrate is provided with a first semiconducting area partially covered by a first masking pattern to define a protected surface and an open surface. A continuous layer of silicon-germanium is deposited in non-selective manner on the first semiconducting area and on the first gate pattern. The continuous silicon-germanium layer forms an interface with the first semiconducting area. A diffusion/condensation annealing is performed to make the germanium atoms diffuse from the silicon-germanium layer to the open surface of the first semiconducting area. The masking pattern is a gate stack of the transistor or is used to define the shape of the gate stack in an electrically insulating layer so as to form a self-aligned gate stack with the source and drain areas.

Abstract: A semiconductive device is fabricated by forming, within a semiconductive substrate, at least one continuous region formed of a material having a non-uniform composition in a direction substantially perpendicular to the thickness of the substrate.

Abstract: A method for manufacturing a transistor includes forming a stack of semiconductor on insulator type layers including at least one substrate, surmounted by a first insulating layer and an active layer to form a channel for the transistor; forming a gate stack on the active layer; producing a source and a drain including forming, on either side of the gate stack, cavities by at least one step of etching the active layer, the first insulating layer, and part of the substrate selectively to the gate stack to remove the active layer, the first insulating layer, and a portion of the substrate outside regions situated below the gate stack; forming a second insulating layer on the bared surfaces of the substrate, to form a continuous insulating layer with the first insulating layer; baring of the lateral ends of the channel; and the filling of the cavities by epitaxy.

Abstract: Fabrication of a microelectronic device on a semiconductor on insulator type substrate, the device being provided with a transistor of a given type, the channel structure of which is formed from semiconducting bar(s), a dielectric area different from the insulating layer of the substrate being provided to replace the insulating layer, facing the transistor channel structure, specifically for this given type of transistor.

Abstract: A process for producing an integrated circuit on the surface of a substrate, the process including: producing a first layer, including active zones and insulating zones, on the surface of the substrate; producing gate zones on the surface of the first layer, the gate zones each being surrounded by insulating spacers; producing source/drain electrodes; producing a dielectric layer between the insulating spacers, the dielectric layer having an upper surface level with the upper surfaces of the gate zones; partially etching each gate zone so as to lower the upper surface of a first part of each gate zone; and depositing an insulating dielectric layer on the first parts of the gate zones.

Abstract: A method for manufacturing a fin MOS transistor from an SOI-type structure including a semiconductor layer on a silicon oxide layer coating a semiconductor support, this method including the steps of: a) forming, from the surface of the semiconductor layer, at least one trench delimiting at least one fin in the semiconductor layer and extending all the way to the surface of the semiconductor support; b) etching the sides of a portion of the silicon oxide layer located under the fin to form at least one recess under the fin; and c) filling the recess with a material selectively etchable over silicon oxide.

Abstract: A method for forming gate, source, and drain contacts on a MOS transistor having an insulated gate including polysilicon covered with a metal gate silicide, this gate being surrounded with at least one spacer made of a first insulating material, the method including the steps of a) covering the structure with a second insulating material and leveling the second insulating material to reach the gate silicide; b) oxidizing the gate so that the gate silicide buries and covers the a silicon oxide; c) selectively removing the second insulating material; and d) covering the structure with a first conductive material and leveling the first conductive material all the way to a lower level at the top of the spacer.

Abstract: A MOS transistor including, above a gate insulator, a conductive gate stack having a height, a length, and a width, this stack having a lower portion close to the gate insulator and an upper portion, wherein the stack has a first length in its lower portion, and a second length shorter than the first length in its upper portion.

Abstract: A method for forming a via connecting a first upper level layer to a second lower level layer, both layers being surrounded with an insulating material, the method including the steps of: a) forming an opening to reach an edge of the first layer, the opening laterally continuing beyond said edge; b) forming a layer of a protection material on said edge only; c) deepening said opening by selectively etching the insulating material to reach the second lower level layer; and d) filling the opening with at least one conductive contact material.

Abstract: A semiconductive device is fabricated by forming, within a semiconductive substrate, at least one continuous region formed of a material having a non-uniform composition in a direction substantially perpendicular to the thickness of the substrate.