Abstract: A method of production of a field-effect transistor from a stack of layers forming a semiconductor-on-insulator type substrate, the stack including a superficial layer of an initial thickness, made of a crystalline semiconductor material and covered with a protective layer, the method including: defining, by photolithography, a gate pattern in the protective layer; etching the gate pattern into the superficial layer to leave a thickness of the layer of semiconductor material in place, the thickness defining a height of a conduction channel of the field-effect transistor; forming a gate in the gate pattern; forming, in the superficial layer and on either side of the gate, source and drain zones, while preserving, in the zones, the initial thickness of the superficial layer.

Abstract: Trenches are formed through a top semiconductor layer and a buried insulator layer of a semiconductor-on-insulator (SOI) substrate. A selective epitaxy is performed to form bulk semiconductor portions filling the trenches and in epitaxial alignment with the semiconductor material of a handle substrate. At least one dielectric layer is deposited over the top semiconductor layer and the bulk semiconductor portions, and is patterned to form openings over selected areas of the top semiconductor layer and the bulk semiconductor portions. A semiconductor alloy material is deposited within the openings directly on physically exposed surfaces of the top semiconductor layer and the bulk semiconductor portions. The semiconductor alloy material intermixes with the underlying semiconductor materials in a subsequent anneal.

Abstract: An integrated circuit includes a silicon substrate, a ground plane above the substrate, a buried insulator layer above the ground plane, a silicon layer above the buried insulator layer and separated from the ground plane by the buried insulator layer, and an FDSOI transistor. The transistor has a channel adapted for being formed in the silicon layer, a source and drain in and/or on the silicon layer, and a gate covering an upper face of the channel and having a lateral portion covering a lateral face of the channel and above the ground plane. A distance between the lateral portion and the ground plane is not more than three nanometers and at least five times less than a thickness of the buried insulator layer between the ground plane and the silicon layer. The ground plane is separated from the gate by the buried insulator layer.

Abstract: A field effect device comprises a substrate of semiconductor on insulator type successively provided with a support substrate, an electrically insulating layer and a semiconductor material film. First and second source/drain electrodes are formed in the semiconductor material layer. A conduction channel is formed in the semiconductor material layer and separates the first and second source/drain electrodes. A counter-electrode is formed in the support substrate and faces the first and second source/drain electrodes and the conduction channel. The counter-electrode is formed by a doped area of the support substrate having a first doping impurity concentration which decreases from an interface between the electrically insulating layer and the support substrate.

Abstract: The field effect device includes an active area made from semi-conducting material and a gate electrode separated from the active area by a dielectric gate material. A counter-electrode is separated from the active area by a layer of electrically insulating material. Two source/drain contacts are arranged on the active area on each side of the gate electrode. One of the source/drain contacts is made from a single material, overspills from the active area and connects the active area with the counter-electrode. The counter-electrode contact is delineated by a closed peripheral insulating pattern.

Abstract: A method of forming a semiconductor-on-insulator (SOI) device includes defining a shallow trench isolation (STI) structure in an SOI substrate, the SOI substrate including a bulk layer, a buried insulator (BOX) layer over the bulk layer, and an SOI layer over the BOX layer; forming a doped region in a portion of the bulk layer corresponding to a lower location of the STI structure, the doped region extending laterally into the bulk layer beneath the BOX layer; selectively etching the doped region of the bulk layer with respect to undoped regions of the bulk layer such that the lower location of the STI structure undercuts the BOX layer; and filling the STI structure with an insulator fill material.

Abstract: The present invention relates to a pair of transistors wherein each transistor of said transistor pair is made of several sub-transistors, and each sub-transistor of a transistor has a sub-transistor channel length and has a sub-transistor channel width, said sub-transistor channel length being substantially equal to the transistor channel length, and said sub-transistor channel width being smaller than the transistor channel width, so that the sum of the sub-transistor channel widths of the sub-transistors of a transistor is substantially equal to the channel width of said transistor, wherein each sub-transistor (43) of a transistor of said transistor pair is spaced apart from at least one adjoining sub-transistor (44) of the other transistor of said transistor pair by a distance D less than half the transistor channel width, said distance d between two sub-transistors (43, 44) being measured between the respective center of the channels of said sub-transistors.

Abstract: The invention provides a method of etching a crystalline semiconductor material (114), the method being characterized in that it comprises: at least one ion implantation performed by implanting a plurality of ions (121) in at least one volume (113) of the semiconductor material (114) in such a manner as to make the semiconductor material amorphous in the at least one implanted volume (113), and as to keep the semiconductor material (114) in a crystalline state outside (112) the at least one implanted volume (113); and at least one chemical etching for selectively etching the amorphous semiconductor material relative to the crystalline semiconductor material, so as to remove the semiconductor material in the at least one volume (113) and so as to keep the semiconductor material outside (112) the at least one volume (113).

Abstract: The present invention relates to a method for manufacturing a semiconductor device by wet-process chemical etching, the device comprising at least one layer of silicon (Si) and at least one layer of silicon-germanium (SiGe) and at least one layer of photosensitive resin forming a mask partly covering the layer of silicon-germanium (SiGe) and leaving the layer of silicon-germanium uncovered in certain zones, characterized in that it comprises a step of preparation of an etching solution, having a pH between 3 and 6, from hydrofluoric acid (HF), hydrogen peroxide (H2O2), acetic acid (CH3COOH) and ammonia (NH4OH), and a step of stripping of the layer of silicon-germanium (SiGe) at least at the said zones by exposure to the said etching solution. The invention will be applicable for the manufacture of integrated circuits and more precisely of transistors. In particular, for optimization of CMOS transistors of the latest generation.

Abstract: The substrate successively includes a support substrate, an electrically insulating layer, a semiconductor material layer, and a gate pattern. The semiconductor material layer and gate pattern are covered by a covering layer. A first doping impurity is implanted in the semiconductor material layer through the covering layer so as to place the thickness of maximum concentration of the first doping impurity in the first layer. The covering layer is partly eliminated so as to form lateral spacers leaving source/drain electrodes free.

Abstract: Methods for semiconductor fabrication include forming a well in a semiconductor substrate. A pocket is formed within the well, the pocket having an opposite doping polarity as the well to provide a p-n junction between the well and the pocket. Defects are created at the p-n junction such that a leakage resistance of the p-n junction is decreased.

Abstract: Trenches are formed through a top semiconductor layer and a buried insulator layer of a semiconductor-on-insulator (SOI) substrate. A selective epitaxy is performed to form bulk semiconductor portions filling the trenches and in epitaxial alignment with the semiconductor material of a handle substrate. At least one dielectric layer is deposited over the top semiconductor layer and the bulk semiconductor portions, and is patterned to form openings over selected areas of the top semiconductor layer and the bulk semiconductor portions. A semiconductor alloy material is deposited within the openings directly on physically exposed surfaces of the top semiconductor layer and the bulk semiconductor portions. The semiconductor alloy material intermixes with the underlying semiconductor materials in a subsequent anneal.

Abstract: The field effect transistor comprises a substrate successively comprising an electrically conducting support substrate, an electrically insulating layer and a semiconductor material layer. The counter-electrode is formed in a first portion of the support substrate facing the semi-conductor material layer. The insulating pattern surrounds the semi-conductor material layer to delineate a first active area and it penetrates partially into the support layer to delineate the first portion. An electrically conducting contact passes through the insulating pattern from a first lateral surface in contact with the counter-electrode through to a second surface. The contact is electrically connected to the counter-electrode.

Abstract: A microelectronic device is provided, including: a substrate including a first semiconductor layer positioned on a dielectric layer and a second semiconductor layer; and an isolation trench disposed through the first semiconductor layer, the dielectric layer, and a part of the thickness of the second semiconductor layer, including a dielectric material and delimiting, in the first semiconductor layer, a roughly rectangular active area of the device, wherein in said part of the thickness of the second semiconductor layer, at least one portion of the dielectric material is positioned under the active area delimited by at least four side walls of the trench, and two of the at least four side walls are roughly parallel with one another and are positioned under the active area, and the other two of the at least four side walls are orthogonal to said two walls and are not positioned under the active area.

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: Methods for semiconductor fabrication include forming a well in a semiconductor substrate. A pocket is formed within the well, the pocket having an opposite doping polarity as the well to provide a p-n junction between the well and the pocket. Defects are created at the p-n junction such that a leakage resistance of the p-n junction is decreased.

Abstract: The present invention relates to a method for producing a microelectronic device having a channel structure formed from superimposed nanowires, in which a nanowire stack having a constant transverse section is firstly formed, followed by a sacrificial gate and insulating spacers, where source and drain areas are then formed by growth of semiconductor material on areas of the stack which are not protected by the sacrificial gate and the insulating spacers (FIG. 4D).

Abstract: A Method for making a separation between an active zone of a substrate located on its front face from a given portion of the substrate located on its back face, wherein trenches and cavities wider than the trenches are formed to extend said trenches, such that at least one given cavity formed to extend a given trench is adjacent to another cavity, and when the cavities have been filled with a given material, they form a separation zone between said active zone and a given portion of the substrate that will be removed later.

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: Method for fabricating a transistor comprising the steps consisting of: forming sacrificial zones in a semi-conductor layer, either side of a transistor channel zone, forming insulating spacers on said sacrificial zones against the sides of the gate of said transistor, removing said sacrificial zones so as to form cavities, with the cavities extending on either side of said channel zone and penetrating under said spacers, forming doped semi-conductor material in said cavities, with said semi-conductor material penetrating under said spacers.