Abstract: Methods and systems for a semiconductor package with high routing density routing patch are disclosed and may include a semiconductor die bonded to a substrate and a high routing density patch bonded to the substrate and to the semiconductor die, wherein the high routing density patch comprises a denser trace line density than the substrate. The high routing density patch can be a silicon-less-integrated module (SLIM) patch, comprising a BEOL portion, and can be TSV-less. Metal contacts may be formed on a second surface of the substrate. A second semiconductor die may be bonded to the substrate and to the high routing density patch. The high routing density patch may provide electrical interconnection between the semiconductor die. The substrate may be bonded to a silicon interposer. The high routing density patch may have a thickness of 10 microns or less. The substrate may have a thickness of 10 microns or less.

Abstract: An exemplary semiconductor device can comprise (a) a substrate comprising a substrate dielectric structure between the substrate top side and the substrate bottom side, conductive pads at the substrate bottom side, and a substrate cavity through the substrate dielectric structure, (b) a base electronic component comprising inner short bumps; outer short bumps bounding a perimeter around the inner short bumps, and tall bumps between the outer short bumps and an edge of the base component top side, and (c) a mounted electronic component coupled to the inner short bumps of the base electronic component. The tall bumps of the base component can be coupled to the conductive pads of the substrate. The mounted electronic component can be located in the substrate cavity. The substrate bottom side can cover at least a portion of the outer short bumps of the base electronic component. Other examples and related methods are disclosed herein.

Abstract: In one example, a semiconductor device, includes a substrate having a top side and a conductor on the top side of the substrate, an electronic device on the top side of the substrate connected to the conductor on the top side of the substrate via an internal interconnect, a lid covering a top side of the electronic device, and a thermal material between the top side of the electronic device and the lid, wherein the lid has a through-hole. Other examples and related methods are also disclosed herein.

Abstract: In one example, an electronic device includes a substrate having a conductive structure. The conductive structure includes a substrate inward terminal at a first side of the substrate and a substrate outward terminal at a second side of the substrate. The substrate includes a dielectric structure with a first opening is at the second side. An electronic component is at the first side of the substrate and is electrically coupled to the substrate inward terminal, and an encapsulant encapsulates the electronic component. The substrate outward terminal comprises one of a multi-via terminal or a multi-stage via. The multi-via terminal includes pad conductive vias in the first opening a pad dielectric via interposed between the pad conductive vias in the first opening and a conductor comprising a conductor top side with micro dimples over the pad conductive vias and the pad dielectric via.

Abstract: In one example, an electronic device includes a substrate with a conductive structure and a substrate encapsulant. The conductive structure has a lead with a lead via and a lead protrusion. The lead via can include via lateral sides defined by first concave portions and the lead protrusion can include protrusion lateral sides defined by second concave portions. The substrate encapsulant covers the first concave portions at a first side of the substrate but not the second concave portions so that the lead protrusion protrudes from the substrate encapsulant at a second side of the substrate. An electronic component can be adjacent to the first side of the substrate and electrically coupled to the conductive structure. A body encapsulant encapsulates portions of the electronic component and the substrate. In some examples, the lead can further include a lead trace at the second side of the substrate. In some examples, the substrate can include a redistribution structure at the first side of the substrate.

Abstract: A semiconductor device with thin redistribution layers is disclosed and may include forming a first redistribution layer on a dummy substrate, electrically coupling a semiconductor die to the first redistribution layer, and forming a first encapsulant layer on the redistribution layer and around the semiconductor die. The dummy substrate may be removed thereby exposing a second surface of the first redistribution layer. A dummy film may be temporarily affixed to the exposed second surface of the redistribution layer and a second encapsulant layer may be formed on the exposed top surface of the semiconductor die, a top surface and side edges of the first encapsulant layer, and side edges of the first redistribution layer. The dummy film may be removed to again expose the second surface of the first redistribution layer, and a second redistribution layer may be formed on the first redistribution layer and on the second encapsulant layer.

Abstract: In one example, a semiconductor structure comprises a redistribution structure comprising a conductive structure, a cavity substrate on a top side of the redistribution structure and having a cavity and a pillar contacting the redistribution structure, an electronic component on the top surface of the redistribution structure and in the cavity, wherein the electronic component is electrically coupled with the conductive structure, and an encapsulant in the cavity and on the top side of the redistribution structure, contacting a lateral side of the electronic component, a lateral side of the cavity, and a lateral side of the pillar. Other examples and related methods are also disclosed herein.

Abstract: In one example, an electronic device comprises a base substrate comprising a base substrate conductive structure, a first electronic component over a first side of the base substrate, an encapsulant over the first side of the base substrate, wherein the encapsulant contacts a lateral side of the electronic component, an interposer substrate over a first side of the encapsulant and comprising an interposer substrate conductive structure, and a vertical interconnect in the encapsulant and coupled with the base substrate conductive structure and the interposer substrate conductive structure. A first one of the base substrate or the interposer substrate comprises a redistribution layer (RDL) substrate, and a second one of the base substrate or the interposer substrate comprises a laminate substrate. Other examples and related methods are also disclosed herein.

Abstract: In one example, a semiconductor device comprises a substrate, an optical device on a top side of the substrate, a translucent cover over the optical device, wherein the translucent cover is a unitary monolithic piece comprising a cover base and a cover pipe. and a cover structure on the top side of the substrate to support the translucent cover over the optical device. Some examples and related methods are also disclosed herein.

Abstract: In one example, a semiconductor device comprises a base assembly comprising a first substrate, a first device on a top surface of the first substrate, and a first encapsulant on the top surface of the first substrate and bounding a side surface of the first device. The semiconductor device further comprises a conductive pillar on the first substrate and in the first molding compound, wherein the conductive pillar comprises a non-conductive pillar core and a conductive pillar shell on the pillar core.

Abstract: Provided is a wiring substrate and its manufacturing method in which a thick wiring layer capable of being applied with a large current and a thin wiring layer capable of being subjected to microfabrication coexist in the same layer. The wiring substrate includes: an insulating film located over a first wiring and having a via; and a second wiring over the insulating film. The second wiring has a stacked structure including a first layer and a second layer covering the first layer. The second layer is in direct contact with the first wiring in the via.

Abstract: A semiconductor device and a method of manufacturing a semiconductor device. For example, various aspects of this disclosure provide a semiconductor device having an ultra-thin substrate, and a method of manufacturing a semiconductor device having an ultra-thin substrate. As a non-limiting example, a substrate structure comprising a carrier, an adhesive layer formed on the carrier, and an ultra-thin substrate formed on the adhesive layer may be received and/or formed, components may then be mounted to the ultra-thin substrate and encapsulated, and the carrier and adhesive layer may then be removed.

Abstract: Provided is a disclosure for optimizing the number of semiconductor devices on a wafer/substrate. The optimization comprises laying out, cutting, and packaging the devices efficiently.

Abstract: In one example, a semiconductor device comprises a first base substrate comprising a first base conductive structure, a first encapsulant contacting a lateral side of the first base substrate, a redistribution structure (RDS) substrate over the base substrate and comprising an RDS conductive structure coupled with the first base conductive structure, a first electronic component over the RDS substrate and over a first component terminal coupled with the RDS conductive structure, and a second encapsulant over the RDS substrate and contacting a lateral side of the first electronic component. Other examples and related methods are also disclosed herein.

Abstract: A packaged electronic device structure includes a substrate having a major surface. A semiconductor device is connected to the major surface of the substrate, the semiconductor device having a first major surface, a second major surface opposite to the first major surface, and a side surface extending between the first major surface and the second major surface. A package body encapsulates a portion of the semiconductor device, wherein the side surface of the semiconductor device is exposed through a side surface of the package body. In some examples, the side surface of the semiconductor device is an active surface. In some examples, the package body comprises a molded structure that contacts and overlaps the first major surface of the semiconductor device.

Abstract: In one example, a method to manufacture a semiconductor device comprises providing an electronic component over a substrate, wherein an interconnect of the electronic component contacts a conductive structure of the substrate, providing the substrate over a laser assisted bonding (LAB) tool, wherein the LAB tool comprises a stage block with a window, and heating the interconnect with a laser beam through the window until the interconnect is bonded with the conductive structure. Other examples and related methods are also disclosed herein.

Abstract: In one example, a system can comprise a laser assisted bonding (LAB) tool comprising a stage block and a laser source facing the stage block. The stage block can be configured to support a first substrate and a first electronic component coupled with the first substrate, the first electronic component comprising a first interconnect. The laser source can be configured to emit a first laser towards the stage block to induce a first heat on the first interconnect to bond the first interconnect with the first substrate. Other examples and related methods are also disclosed herein.

Abstract: A semiconductor device and a method of manufacturing a semiconductor device. As a non-limiting example, various aspects of this disclosure provide a stackable semiconductor device with small size and fine pitch and a method of manufacturing thereof.

Abstract: In one example, a semiconductor device structure relates to an electronic device, which includes a device top surface, a device bottom surface opposite to the device top surface, device side surfaces extending between the device top surface and the device bottom surface, and pads disposed over the device top surface. Interconnects are connected to the pads, and the interconnects first regions that each extend from a respective pad in in an upward direction, and second regions each connected to a respective first region, wherein each second region extends from the respective first region in a lateral direction. The interconnects comprise a redistribution pattern on the pads. Other examples and related methods are also disclosed herein.

Abstract: A method for manufacturing a semiconductor device and a semiconductor device produced thereby. For example and without limitation, various aspects of this disclosure provide a method for manufacturing a semiconductor device, and a semiconductor device produced thereby, that comprises an interposer without through silicon vias.