Abstract: A method for manufacturing an electronic device based on SiC includes forming a structural layer of SiC on a front side of a substrate. The substrate has a back side that is opposite to the front side along a direction. Active regions of the electronic device are formed in the structure layer, and the active regions are configured to generate or conduct electric current during the use of the electronic device. A first electric terminal is formed on the structure layer, and an intermediate layer is formed at the back side of the substrate. The intermediate layer is heated by a LASER beam in order to generate local heating such as to favor the formation of an ohmic contact of Titanium compounds. A second electric terminal of the electronic device is formed on the intermediate layer.

Abstract: A method for manufacturing an electronic device based on SiC includes forming a structural layer of SiC on a front side of a substrate. The substrate has a back side that is opposite to the front side along a direction. Active regions of the electronic device are formed in the structure layer, and the active regions are configured to generate or conduct electric current during the use of the electronic device. A first electric terminal is formed on the structure layer, and an intermediate layer is formed at the back side of the substrate. The intermediate layer is heated by a LASER beam in order to generate local heating such as to favor the formation of an ohmic contact of Titanium compounds. A second electric terminal of the electronic device is formed on the intermediate layer.

Abstract: A process for manufacturing a silicon carbide device from a body of silicon carbide having a back surface, wherein a first layer of a first metal is formed on the back surface of the body; a second layer of a second metal, different from the first metal, is formed on the first layer to form a multilayer, the first or the second metal being nickel or a nickel alloy and forming a nickel-based layer, another of the first or the second metal being a metal X, capable to form stable compounds with carbon and forming an X-based layer; and the multilayer is annealed to form a mixed layer including nickel silicide and at least one of X carbide or a metal X-carbon ternary compound.

Abstract: For the manufacturing of a vertical conduction silicon carbide electronic device, a work wafer, which has a silicon carbide substrate having a work face, is processed. A rough face is formed from the work face of the silicon carbide substrate. The rough face has a roughness higher than a threshold. A metal layer is deposited on the rough face and the metal layer is annealed, thereby causing the metal layer to react with the silicon carbide substrate, forming a silicide layer having a plurality of protrusions of silicide.

Abstract: A metal layer is deposited on a wafer that has silicon carbide, wherein the metal layer forms a contact face. A laser annealing is performed at the contact face using a laser beam application that causes the metal layer to react with the wafer and form a silicide layer. The laser beam has a footprint having a size. To laser anneal the contact face, a first portion of the contact face is irradiated, the footprint of the laser beam is moved by a step smaller than the size of the footprint, and a second portion of the contact face is irradiated, thereby causing the first portion and the second portion of the contact face to overlap.

Abstract: A process for manufacturing a silicon carbide semiconductor device includes providing a silicon carbide wafer, having a substrate. An epitaxial growth for formation of an epitaxial layer, having a top surface, is carried out on the substrate. Following upon the step of carrying out an epitaxial growth, the process includes the step of removing a surface portion of the epitaxial layer starting from the top surface so as to remove surface damages present at the top surface as a result of propagation of dislocations from the substrate during the previous epitaxial growth and so as to define a resulting top surface substantially free of defects.

Abstract: A method for manufacturing a SiC-based electronic device, comprising the steps of: implanting, on a front side of a solid body made of SiC having a conductivity of an N type, dopant species of a P type thus forming an implanted region, which extends in the solid body starting from the front side and has a top surface coplanar with the front side; and generating a laser beam directed towards the implanted region in order to generate heating of the implanted region to temperatures comprised between 1500° C. and 2600° C. so as to form a carbon-rich electrical-contact region at the implanted region. The carbon-rich electrical-contact region forms an ohmic contact.

Abstract: A method for manufacturing an electronic device based on SiC includes forming a structural layer of SiC on a front side of a substrate. The substrate has a back side that is opposite to the front side along a direction. Active regions of the electronic device are formed in the structure layer, and the active regions are configured to generate or conduct electric current during the use of the electronic device. A first electric terminal is formed on the structure layer, and an intermediate layer is formed at the back side of the substrate. The intermediate layer is heated by a LASER beam in order to generate local heating such as to favor the formation of an ohmic contact of Titanium compounds. A second electric terminal of the electronic device is formed on the intermediate layer.

Abstract: It is described an electronic device 1 comprising a temperature detection component 2 and an integrated electronic power component 3, the device being adapted to be mounted on the substrate S. The electronic integrated power component 3 has a first surface portion 31, adapted to be mounted on the substrate S, and a second surface portion 32, opposite to the first surface portion. The temperature detection component 2 comprises two sensor terminals 21, 22, adapted to be connected to the substrate S by means of wire bonding W, and further comprises a temperature sensor 20, configured to detect a temperature T representative of the temperature T3 of the integrated electronic power component 3 and to provide, by means of the two sensor terminals 21, 22, an electrical signal V representative of the detected temperature T.

Abstract: A container with diffuse and extended irrigation for cultivating plants, which includes porous regions in the containment walls, which are arranged in contact with the soil of a plant, and a water reserve for supplying the porous regions. The container further includes a waterproofing layer for covering the porous regions, in their parts that are not in contact, for preventing the water from being lost by evaporation from the porous regions toward the outside of the container. The invention solves the problems of conventional containers, providing the soil with the right amount of moisture in an extremely simple manner for several days, accordingly avoiding periodic watering.

Abstract: A container with diffuse and extended irrigation for cultivating plants, which includes porous regions in the containment walls, which are arranged in contact with the soil of a plant, and a water reserve for supplying the porous regions. The container further includes a waterproofing layer for covering the porous regions, in their parts that are not in contact, for preventing the water from being lost by evaporation from the porous regions toward the outside of the container. The invention solves the problems of conventional containers, providing the soil with the right amount of moisture in an extremely simple manner for several days, accordingly avoiding periodic watering.

Abstract: Process for the manufacturing of a DMOS-technology transistor, providing for forming, over a semiconductor material layer of a first conductivity type, an insulated gate electrode, introducing in said semiconductor material layer a first dopant of a second conductivity type for forming at least one body region of a second conductivity type extending under the insulated gate electrode, and introducing in said at least one body region a second dopant of the first conductivity type for forming, inside said body region, at least one source region of the first conductivity type, said body region and said source region defining, under the insulated gate electrode, a channel region for the DMOS transistor, wherein said first dopant is aluminum. After the introduction of said first dopant and said second dopant, a single thermal diffusion process for simultaneously diffusing the first dopant and the second dopant is provided.

Abstract: A fabrication method for high voltage power devices with at least one deep edge ring includes the steps of growing a lightly doped N-type epitaxial layer on a heavily doped N-type substrate, growing an oxide on the upper portion of the epitaxial layer, masking and then implanting boron ions, etching the oxide to expose regions for aluminum ion implantation, forming a layer of preimplantation oxide, masking of the body regions with a layer of photosensitive material and implanting aluminum ions, and a single thermal diffusion process forming a layer of thermal oxide on the epitaxial layer and simultaneously forming at least one deep aluminum ring and an adjacent body region doped with boron.

Abstract: There is disclosed a blind slat to be used particularly for vertical blinds wherein at least the outer surface is formed with regularly distributed successive corrugations. In practice, the inner face is also corrugated. The slat is extruded from a plastic material of one basic color and preselected opposite surfaces forming the corrugations are of a color which is different from the basic color. Some or all of the remaining opposite surfaces have the basic color or a color which different from the basic color and from the color of the preselected opposite surfaces. Such blind slat is particularly useful to create special effects for example by vertical blinds. The method and the apparatus for producing these blind slats are also disclosed.