Abstract: pa The method of processing a semiconductor wafer includes forming one or more epitaxial layers over its first main surface. It also involves forming one or more porous layers within the semiconductor wafer or within the epitaxial layers. Together, the semiconductor wafer, the epitaxial layer(s), and the porous layer(s) form a substrate. Next, doped regions of a semiconductor device are formed within the epitaxial layer(s). After forming these doped regions, a non-porous part of the semiconductor wafer is separated from the rest of the substrate along the porous layer(s).

Abstract: A method of manufacturing a silicon carbide device includes forming a transfer foil that includes a porous silicon carbide layer. A composite substrate is formed that includes the transfer foil and a support substrate. The transfer foil and the support substrate are brought into contact with each other and connected to each other. An epitaxial layer is formed on a side of the porous silicon carbide layer opposite to the support substrate. The composite substrate is divided into a device substrate and a reclaim substrate. The device substrate includes the epitaxial layer and the reclaim substrate includes the support substrate.

Abstract: A method of manufacturing a semiconductor device includes: providing a silicon carbide substrate that includes device regions and a grid-shaped kerf region laterally separating the device regions; forming a mold structure on a backside surface of the grid-shaped kerf region; forming backside metal structures on a backside surface of the device regions; and separating the device regions, wherein parts of the mold structure form frame structures laterally surrounding the backside metal structures.

Abstract: A method of manufacturing a semiconductor device in a semiconductor body is proposed. The method includes processing a semiconductor body at a first surface of the semiconductor body. The method further includes attaching the semiconductor body to a carrier via the first surface. The carrier includes an inner part and an outer part at least partly surrounding the inner part. The method further includes processing the semiconductor body at a second surface opposite to the first surface. The method further includes detaching the inner part of the carrier from the semiconductor body.

Abstract: A semiconductor wafer includes: a first main surface and a second main surface opposite the first main surface; a detachment plane parallel to the first main surface inside the semiconductor wafer, the detachment plane defined by defects; electronic semiconductor components formed at the first main surface and between the first main surface and the detachment plane; and a glass structure attached to the first main surface. The glass structure includes openings, each of which leaves a respective area of the electronic semiconductor components uncovered. A method of processing the wafer, a clip, and a semiconductor device are also described.

Abstract: A method for processing a semiconductor wafer is provided. A semiconductor wafer includes a first main surface and a second main surface. Defects are generated inside the semiconductor wafer to define a detachment plane parallel to the first main surface. Processing the first main surface defines a plurality of electronic semiconductor components. A glass structure is provided which includes a plurality of openings. The glass structure is attached to the processed first main surface, each of the plurality of openings leaving a respective area of the plurality of electronic semiconductor components uncovered. A polymer layer is applied to the second main surface and the semiconductor wafer is split into a semiconductor slice and a remaining semiconductor wafer by cooling the polymer layer beneath its glass transition temperature along the detachment plane. The semiconductor slice includes the plurality of electronic semiconductor components.

Abstract: A method of processing a semiconductor wafer includes: forming one or more epitaxial layers over a first main surface of the semiconductor wafer; forming one or more porous layers in the semiconductor wafer or in the one or more epitaxial layers, wherein the semiconductor wafer, the one or more epitaxial layers and the one or more porous layers collectively form a substrate; forming doped regions of a semiconductor device in the one or more epitaxial layers; and after forming the doped regions of the semiconductor device, separating a non-porous part of the semiconductor wafer from a remainder of the substrate along the one or more porous layers.

Abstract: A method of manufacturing a semiconductor device is described. The method includes providing a parent substrate including a substrate portion of a first conductivity type. The method further includes forming an absorption layer in the parent substrate by an ion implantation process of an element through a first surface of the parent substrate. The method further includes forming a semiconductor layer structure on the first surface of the parent substrate. The method further includes splitting the parent substrate along a splitting section through a detachment layer. The detachment layer is arranged between the absorption layer and a second surface of the parent substrate at a vertical distance to the absorption layer.

Abstract: A carrier configured to be attached to a semiconductor substrate via a first surface comprises a continuous carbon structure defining a first surface of the carrier, and a reinforcing material constituting at least 2 vol-% of the carrier.

Abstract: A wafer composite includes a handle substrate, an auxiliary layer formed on a first main surface of the handle substrate, and a silicon carbide structure formed over the auxiliary layer. The handle substrate is subjected to laser radiation that modifies crystalline material along a focal plane in the handle substrate. The focal plane is parallel to the first main surface. The auxiliary layer is configured to stop propagation of microcracks that the laser radiation may generate in the handle substrate.

Abstract: A method of manufacturing a semiconductor device includes: providing a silicon carbide substrate that includes device regions and a grid-shaped kerf region laterally separating the device regions; forming a mold structure on a backside surface of the grid-shaped kerf region; forming backside metal structures on a backside surface of the device regions; and separating the device regions, wherein parts of the mold structure form frame structures laterally surrounding the backside metal structures.

Abstract: An auxiliary carrier and a silicon carbide substrate are provided. The silicon carbide substrate includes an idle layer and a device layer between a main surface at a front side of the silicon carbide substrate and the idle layer. The device layer includes a plurality of laterally separated device regions. Each device region extends from the main surface to the idle layer. The auxiliary carrier is structurally connected with the silicon carbide substrate at the front side. The idle layer is removed. A mold structure is formed that fills a grid-shaped groove that laterally separates the device regions. The device regions are separated, and parts of the mold structure form frame structures laterally surrounding the device regions.

Abstract: According to an embodiment of a method described herein, a silicon carbide substrate is provided that includes a plurality of device regions. A front side metallization may be provided at a front side of the silicon carbide substrate. The method may further comprise providing an auxiliary structure at a backside of the silicon carbide substrate. The auxiliary structure includes a plurality of laterally separated metal portions. Each metal portion is in contact with one device region of the plurality of device regions.

Abstract: A method for processing a semiconductor wafer is provided. A semiconductor wafer includes a first main surface and a second main surface. Defects are generated inside the semiconductor wafer to define a detachment plane parallel to the first main surface. Processing the first main surface defines a plurality of electronic semiconductor components. A glass structure is provided which includes a plurality of openings. The glass structure is attached to the processed first main surface, each of the plurality of openings leaving a respective area of the plurality of electronic semiconductor components uncovered. A polymer layer is applied to the second main surface and the semiconductor wafer is split into a semiconductor slice and a remaining semiconductor wafer by cooling the polymer layer beneath its glass transition temperature along the detachment plane. The semiconductor slice includes the plurality of electronic semiconductor components.

Abstract: A wafer composite includes a handle substrate, an auxiliary layer formed on a first main surface of the handle substrate, and a silicon carbide structure formed over the auxiliary layer. The handle substrate is subjected to laser radiation that modifies crystalline material along a focal plane in the handle substrate. The focal plane is parallel to the first main surface. The auxiliary layer is configured to stop propagation of microcracks that the laser radiation may generate in the handle substrate.

Abstract: An auxiliary carrier and a silicon carbide substrate are provided. The silicon carbide substrate includes an idle layer and a device layer between a main surface at a front side of the silicon carbide substrate and the idle layer. The device layer includes a plurality of laterally separated device regions. Each device region extends from the main surface to the idle layer. The auxiliary carrier is structurally connected with the silicon carbide substrate at the front side. The idle layer is removed. A mold structure is formed that fills a grid-shaped groove that laterally separates the device regions. The device regions are separated, and parts of the mold structure form frame structures laterally surrounding the device regions.

Abstract: A carrier configured to be attached to a semiconductor substrate via a first surface comprises a continuous carbon structure defining a first surface of the carrier, and a reinforcing material constituting at least 2 vol-% of the carrier.

Abstract: According to an embodiment of a method described herein, a silicon carbide substrate is provided that includes a plurality of device regions. A front side metallization may be provided at a front side of the silicon carbide substrate. The method may further comprise providing an auxiliary structure at a backside of the silicon carbide substrate. The auxiliary structure includes a plurality of laterally separated metal portions. Each metal portion is in contact with one device region of the plurality of device regions.

Abstract: The present disclosure relates to a method for manufacturing a multi-junction solar cell device comprising the steps of: providing a first substrate with a lower surface and an upper surface; providing a second substrate with a lower surface and an upper surface; bonding the first substrate to the second substrate at the upper surface of the first substrate and the lower surface of the second substrate; and subsequently forming at least one first solar cell layer on the lower surface of the first substrate and at least one second solar cell layer at the upper surface of the second substrate.

Abstract: A method of fabricating a heterostructure comprising at least a first substrate (120) made of sapphire and a second substrate (110) made of a material having a coefficient of thermal expansion that is different from that of the first substrate. The method includes a step (S6) of molecular bonding the second substrate (110) on the first substrate (120) made of sapphire. The method also includes, prior to bonding the two substrates together, a step (S1) of stoving the first substrate (120) at a temperature that lies in the range 100° C. to 500° C.