A pattern of microchannels is formed on a major surface of a substrate on the side opposite an adhesive surface thereof. Through holes extend through the substrate and are connected to the pattern of microchannels. Solid circuit dies are adhesively bonded to the adhesive surface of the substrate. The contact pads of the solid circuit dies at least partially overlie and face the through holes. Electrically conductive channel traces are formed to electrically connect to the solid circuit dies via the through holes.

Flexible devices including conductive traces with enhanced stretchability, and methods of making and using the same are provided. The circuit die is disposed on a flexible substrate. Electrically conductive traces are formed in channels on the flexible substrate to electrically contact with contact pads of the circuit die. A first polymer liquid flows in the channels to cover a free surface of the traces. The circuit die can also be surrounded by a curing product of a second polymer liquid.

In an embodiment, a device includes: a bottom integrated circuit die having a first front side and a first back side; a top integrated circuit die having a second front side and a second back side, the second back side being bonded to the first front side, the top integrated circuit die being free from through substrate vias (TSVs); a dielectric layer surrounding the top integrated circuit die, the dielectric layer being disposed on the first front side, the dielectric layer and the bottom integrated circuit die being laterally coterminous; and a through via extending through the dielectric layer, the through via being electrically coupled to the bottom integrated circuit die, surfaces of the through via, the dielectric layer, and the top integrated circuit die being planar.

A method of manufacturing an electronic package is disclosed. The described method includes (a) placing an electronic component on at least one layer structure; (b) encapsulating the electronic component by an encapsulant in a pressureless way; and (c) forming at least one further layer structure at the layer structure to thereby form a stack beneath the encapsulated electronic component. A further described electronic package includes (a) a stack comprising at least one layer structure and at least one further layer structure; (b) an electronic component being placed on the stack; and (c) an encapsulant encapsulating the electronic component, wherein the encapsulant has been formed in a pressureless way. Further described is an electronic device comprising such an electronic package.

An electronic substrate may be fabricated having at least two glass layers separated by an etch stop layer, wherein a bridge is embedded within one of the glass layers. The depth of a cavity formed for embedding the bridge is control by the thickness of the glass layer rather than by controlling the etching process used to form the cavity, which allows for greater precision in the fabrication of the electronic substrate. In an embodiment of the present description, an integrated circuit package may be formed with the electronic substrate, wherein at least two integrated circuit devices may be attached to the electronic substrate, such that the bridge provides device-to-device interconnection between the at least two integrated circuit devices. In a further embodiment, the integrated circuit package may be electrically attached to an electronic board.

A method comprises: providing a layer of curable adhesive material (4) on a substrate (2); forming a pattern of microstructures (321) on the layer of curable adhesive material (4); curing a first region (42) of the layer of curable adhesive material (4) at a first level and a second region (44) of the layer of curable adhesive material (4) at a second level greater than the first level; providing a solid circuit die (6) to directly attach to a major surface of the first region (42) of the layer of curable adhesive material (4); and further curing the first region (42) of the layer of curable adhesive material (4) to anchor the solid circuit die (6) on the first region (42) by forming an adhesive bond therebetween. The pattern of microstructures (321) may include one or more microchannels (321), the method further comprising forming one or more electrically conductive traces in the microchannels (321), in particular, by flow of a conductive particle containing liquid (8) by a capillary force and, optionally, under pressure. The at least one microchannel (321) may extend from the second region (44) to the first region (42) and have a portion beneath the solid circuit die (6). The solid circuit die (6) may have at least one edge disposed within a periphery of the first region (42) with a gap therebetween. The solid circuit die (6) may have at least one contact pad (72) on a bottom surface thereof, wherein the at least one contact pad (72) may be in direct contact with at least one of the electrically conductive traces in the microchannels (321). Forming the pattern of microstructures (321) may comprise contacting a major surface of a stamp (3) to the layer of curable adhesive material (4), the major surface having a pattern of raised features (32) thereon. The curable adhesive material (4) may be cured by an actinic light source such as an ultraviolet (UV) light source (7, 7′), wherein a mask may be provided to at least partially block the first region (42) of the layer of curable adhesive material (4) from the cure. The stamp (3) may be positioned in contact with the curable adhesive material (4) to replicate the pattern of raised features (32) to form the microstructures (321) while the curable adhesive material (4) is selectively cured by the actinic light source such as the ultraviolet (UV) light source (7). The first region (42) of the layer of curab

A microelectronic assembly is disclosed, comprising: a substrate having a core made of glass; and a first integrated circuit (IC) die and a second IC die coupled to a first side of the substrate. The core comprises a cavity, a third IC die is located within the cavity, and the core further comprises one or more conductive through-glass via (TGV) that facilitates electrical coupling between the first side of the substrate and an opposing second side of the substrate. In some embodiments, the cavity is a blind cavity; in other embodiments, the cavity is a through-hole. In some embodiments, the third IC die merely provides lateral coupling between the first IC die and the second IC die; in other embodiments, the third IC die also provides electrical coupling between the first side and the second side of the substrate with through-silicon vias.

A package structure includes a first dielectric layer, semiconductor device(s) attached to the first dielectric layer, and an embedding material applied to the first dielectric layer so as to embed the semiconductor device therein, the embedding material comprising one or more additional dielectric layers. Vias are formed through the first dielectric layer to the at least one semiconductor device, with metal interconnects formed in the vias to form electrical interconnections to the semiconductor device. Input/output (I/O) connections are located on one end of the package structure on one or more outward facing surfaces thereof to provide a second level connection to an external circuit. The package structure interfits with a connector on the external circuit to mount the package perpendicular to the external circuit, with the I/O connections being electrically connected to the connector to form the second level connection to the external circuit.

A packaged integrated circuit includes a core structure with a cavity therein; a component accommodated in the cavity; an electrically insulating structure formed over the core structure and the component; a partially electrically insulating carrier structure formed below the core structure and the component; and an electrically conducting redistribution arrangement formed at least partially within the carrier structure. The redistribution arrangement includes conductor structures each having a first element extending through the carrier structure and electrically connecting a contact of the component and a second element below the carrier structure. A part of the second element is a contact pad for electrically connecting the redistribution arrangement with external circuitry. The carrier structure includes a polyimide layer and an adhesive layer. The adhesive layer is directly attached to an upper surface of the polyimide layer and to a lower surface of the core structure and a lower surface of the component.

A device is provided. The device includes a bridge layer over a first substrate. A first connector electrically connecting the bridge layer to the first substrate. A first die is coupled to the bridge layer and the first substrate, and a second die is coupled to the bridge layer.