Abstract: An optoelectronic semiconductor device may include a carrier comprising a patterned surface and a semiconductor layer sequence arranged on the carrier. The semiconductor layer sequence may include a first semiconductor layer having a first surface, a second semiconductor layer having a first surface, and a first main surface and a second main surface opposite the first main surface. The first surfaces of the first and second semiconductor layers may be at least partly arranged at the first main surface. The second main surface may face the patterned surface of the carrier, and at least one side face may connect the first and second main surfaces. The device may further include a directionally reflective layer and a planarization layer. The planarization layer may be arranged between the patterned surface and the directionally reflective layer. Moreover, a method for producing an optoelectronic semiconductor device is also disclosed.

Abstract: In an embodiment a composite semiconductor component includes a carrier substrate having a plurality of projecting elements projecting from a first main surface of the carrier substrate, an electrically conductive material electrically conductively connected to a contact region of the carrier substrate and located on at least one of the projecting elements, some of the projecting elements not being covered with the electrically conductive material and a semiconductor chip arranged on the carrier substrate and having at a first surface at least one contact pad electrically connected to the electrically conductive material on at least one element, wherein, at a position at which the contact pad and the electrically conductive material on the projecting element are in each case in contact with one another, the contact pad has a larger lateral extent than the projecting element in each case.

Abstract: A component assembly includes an intermediate carrier, a plurality of components and a plurality of anchoring elements. The components have at least two electrical devices and an insulating layer. At least one of the electrical devices is an optoelectronic semiconductor chip. The insulating layer is between the electrical devices of a same component. The at least two electrical devices of the same component are arranged next to one another and enclosed laterally by the insulating layer. The at least two electrical devices and the insulating layer of the same component are integral parts of a self-supporting and mechanically stable unit. The self-supporting and mechanically stable unit and the anchoring elements fix the positions of the components on the intermediate carrier. The components that are self-supporting and mechanically stable units are detachable from the intermediate carrier, and the anchoring elements release the components under mechanical load when the latter are removed.

Abstract: In an embodiment a method for producing a component having a carrier and at least one component part electrically conductively connected to the carrier and mechanically fixed to the carrier by an electrically insulating bonding layer includes providing the carrier having a connection layer, wherein the bonding layer is disposed on the carrier and has at least one opening, wherein a connection surface of the connection layer is exposed, and wherein the bonding layer projects vertically beyond the exposed connection surface or vice versa, applying the component part having a contact layer on the carrier in such that, in top view of the carrier, an exposed contact surface of the contact layer covers the opening and the connection surface located therein, wherein the exposed contact surface is spaced apart from the exposed connection surface by a vertical distance and reducing the vertical distance by changing a volume of the bonding layer such that the exposed contact surface and the exposed connection surface a

Abstract: An optoelectronic semiconductor device may include a carrier having a roughened first main surface and optoelectronic semiconductor chips arranged over the roughened first main surface. The combined surface area of the optoelectronic semiconductor chips is smaller than the surface area of the carrier, and a part of the roughened first main surface is arranged between adjacent optoelectronic semiconductor chips.

Abstract: The method of manufacturing a plurality of semiconductor chips (100) comprises a step A) of providing a semiconductor substrate (1) having a plurality of integrated electronic circuits (2) on a top side (10) thereof. In a step B), a sacrificial layer (3) is applied on one side of the semiconductor substrate. In a step C), holes (30) are introduced in the sacrificial layer so that at least one hole is formed above each electronic circuit. In a step D), the semiconductor substrate is adhered to a carrier (5) with the sacrificial layer at the front, an adhesive layer (4) being used between the sacrificial layer and the carrier, and the adhesive layer filling the holes so that holding elements (40) from the adhesive layer are formed in the holes. In a step E) the semiconductor substrate is thinned.

Abstract: A component may have a semiconductor body, a first electrode, and a second electrode. The first electrode and the second electrode may be configured for electrically contacting a first semiconductor layer and a second semiconductor, respectively, and may have a first distribution track and a second distribution track for uniformly distributing current in the first semiconductor layer and the second semiconductor layer, respectively. The first distribution track and the second distribution track may be arranged regionally one above the other on the same side of the semiconductor body, overlap each other regionally in top view, and cover the semiconductor body only in certain places. Furthermore, the first distribution track may extend in places throughout the second semiconductor layer and the active zone to the first semiconductor layer. The active zone may be removed only in places in overlapping regions of the semiconductor body and the first distribution track.

Abstract: In an embodiment, a multi-chip module includes a first carrier including a mold material and at least two light-emitting diode chips embedded at least by side faces in the first carrier, wherein the light-emitting diode chips have first electrical contacts on a front side and second electrical contacts on a rear side, wherein the front side is configured as a radiation side, wherein the first electrical contacts are connected to control lines, wherein the control lines are arranged on a front side of the first carrier, wherein the second electrical contacts are connected to a collective line, and wherein the collective line is led to a rear side of the first carrier.

Abstract: A method for producing a component and a component are disclosed. In an embodiment a method includes providing a substrate, applying a composite of components to the substrate, forming an anchoring layer on the composite of components, attaching a carrier to the anchoring layer, wherein the anchoring layer is disposed between the substrate and the carrier and removing the substrate, wherein the composite of components is divided into a plurality of components by forming a plurality of separating trenches, wherein, after removing the substrate, the components continue to be held on the carrier by the anchoring layer, and wherein the anchoring layer comprises at least one predetermined breaking layer having at least one predetermined breaking position, the predetermined breaking position being laterally surrounded by the separating trenches and—in a plan view of the carrier—being covered by one of the components.

Abstract: A component assembly includes an intermediate carrier, a plurality of components and a plurality of anchoring elements. The components have at least two electrical devices and an insulating layer. At least one of the electrical devices is an optoelectronic semiconductor chip. The insulating layer is between the electrical devices of a same component. The at least two electrical devices of the same component are arranged next to one another and enclosed laterally by the insulating layer. The at least two electrical devices and the insulating layer of the same component are integral parts of a self-supporting and mechanically stable unit. The self-supporting and mechanically stable unit and the anchoring elements fix the positions of the components on the intermediate carrier. The components that are self-supporting and mechanically stable units are detachable from the intermediate carrier, and the anchoring elements release the components under mechanical load when the latter are removed.

Abstract: A method for transferring semiconductor bodies and a semiconductor chip are disclosed.

Abstract: In an embodiment a composite semiconductor component includes a carrier substrate having a plurality of projecting elements projecting from a first main surface of the carrier substrate, an electrically conductive material electrically conductively connected to a contact region of the carrier substrate and located on at least one of the projecting elements, some of the projecting elements not being covered with the electrically conductive material and a semiconductor chip arranged on the carrier substrate and having at a first surface at least one contact pad electrically connected to the electrically conductive material on at least one element, wherein, at a position at which the contact pad and the electrically conductive material on the projecting element are in each case in contact with one another, the contact pad has a larger lateral extent than the projecting element in each case.

Abstract: A mount (10) and an optoelectronic component (100) with the mount (10) are provided, wherein the mount (10) comprises a moulding (5), at least one through-contact (41, 42) and a plurality of reinforcing fibres (52), wherein the moulding (5) is formed from an electrically insulating moulding material (53), the through-contact (41, 42) is formed from an electrically conductive material, and the reinforcing fibres (52) produce a mechanical connection between the moulding (5) and the through-contact (41, 42) by the reinforcing fibres (52) being arranged in certain regions of the moulding (5) and arranged in certain regions of the through-contact (41, 42). A method for producing a mount or a component with such a mount is also provided.

Abstract: The method of manufacturing a plurality of semiconductor chips (100) comprises a step A) of providing a semiconductor substrate (1) having a plurality of integrated electronic circuits (2) on a top side (10) thereof. In a step B), a sacrificial layer (3) is applied on one side of the semiconductor substrate. In a step C), holes (30) are introduced in the sacrificial layer so that at least one hole is formed above each electronic circuit. In a step D), the semiconductor substrate is adhered to a carrier (5) with the sacrificial layer at the front, an adhesive layer (4) being used between the sacrificial layer and the carrier, and the adhesive layer filling the holes so that holding elements (40) from the adhesive layer are formed in the holes. In a step E) the semiconductor substrate is thinned.

Abstract: An optoelectronic semiconductor chip includes a semiconductor body including a first semiconductor region, a second semiconductor region and an active zone disposed between the first and second semiconductor regions, an electrically conductive contact layer arranged on a side of the first semiconductor region facing away from the second semiconductor region, and an electrically conductive mirror layer arranged between the first semiconductor region and the electrically conductive contact layer, and laterally protruding at the edge by the first semiconductor region and the electrically conductive contact layer so that between the first semiconductor region and the electrically conductive contact layer there is an interspace in which a protective layer is arranged for protecting the mirror layer, wherein the electrically conductive contact layer extends laterally to an edge of the first semiconductor region, and the electrically conductive contact layer consists of Ni.

Abstract: A component having a metal carrier and a method for producing a component are disclosed. In an embodiment the component includes a carrier having a metallic carrier layer, an insulating layer and a first through-contact extending in a vertical direction throughout the carrier layer, wherein the through-contact is electrically isolated from the carrier layer via the insulating layer. The component further includes a semiconductor body and a wiring structure arranged in the vertical direction between the carrier and the semiconductor body at least places and electrically contacting the semiconductor body, wherein the wiring structure has a first connection area and a second connection area, wherein the connection areas adjoin the carrier and are assigned to different electrical polarities of the component, wherein the first through-contact is in electrical contact with one of the connection areas, and wherein the component is configured to be externally electrically connectable via the carrier.

Abstract: A method for producing a component may include providing a composite including a semiconductor layer stack, a first connection layer and a second connection layer, wherein the first and second connection layers are arranged on the semiconductor layer stack, are assigned to different electrical polarities and are configured for the electrical contacting of the component to be produced, applying a molded body material on the composite for forming a molded body, such that in a plan view of the semiconductor layer stack the molded body covers the first connection layer and the second connection layer, forming a first cutout and a second cutout through the molded body for exposing the connection layers in places, and filling the first and second cutouts with an electrically conductive material for forming through contacts which are electrically conductively connected to the connection layers and extend through the molded body in the vertical direction.

Abstract: A method of producing an optoelectronic component includes providing an optoelectronic semiconductor chip having a first surface on which a first electrical contact and a second electrical contact are arranged; arranging a protection diode on the first contact and the second contact; galvanically growing a first pin on the first electrical contact and a second pin on the second electrical contact; and embedding the first pin, the second pin, and the protection diode in a molded body.

Abstract: A light-emitting semiconductor chip and a method for producing a light-emitting semiconductor chip are disclosed. In an embodiment a light-emitting chip includes a semiconductor body having an active region designed to generate light, a dielectric mirror including an electrically insulating material and a first metallic mirror including an electrically conductive material, wherein the semiconductor body expands towards a light exit side, wherein the dielectric mirror is arranged on a side of the semiconductor body facing away from the light exit side, wherein the first metallic mirror is arranged on a side of the dielectric mirror facing away from the semiconductor body, wherein the first metallic mirror electrically contacts the semiconductor body through at least one opening in the dielectric mirror, and wherein the dielectric mirror, apart from the at least one opening, completely covers the semiconductor body on the side facing away from the light exit side.

Abstract: The invention relates, inter alia, to a method for producing a plurality of semiconductor chips, the method comprising the following steps: providing a substrate (1); applying a semiconductor layer sequence (2) to the substrate (1); generating a plurality of recesses (6) in the semiconductor layer sequence (2) on the side of the semiconductor layer sequence (2) that is facing away from the substrate (1); detaching the substrate (1) from the semiconductor layer sequence (2); thinning the semiconductor layer sequence (2) on the side that was facing the substrate (1) prior to detaching the substrate (1).