There is provided a method of manufacturing a multilayer wiring board including: alternately stacking wiring layers and insulating layers; stacking a reinforcing sheet having openings on one surface of the resulting multilayer laminate with a soluble adhesive layer therebetween; contacting or infiltrating the soluble adhesive layer with a liquid capable of dissolving the soluble adhesive layer through the openings to thereby dissolve or soften the soluble adhesive layer; and releasing the reinforcing sheet from the multilayer laminate at the position of the soluble adhesive layer. This method enables the multilayer wiring layer to be reinforced so as to generate no large local warpage, thereby improving the reliable connection in the multilayer wiring layer and the flatness (coplanarity) on the surface of the multilayer wiring layer. The reinforcing sheet having finished its role can be released in a significantly short time, while minimizing the stress applied to the multilayer laminate.

A printed structure includes a destination substrate comprising two or more contact pads disposed on or in a surface of the destination substrate, a component disposed on the surface, and two or more electrically conductive connection posts. Each of the connection posts extends from a common side of the component. Each of the connection posts is in electrical and physical contact with one of the contact pads. The component is tilted with respect to the surface of the destination substrate. Each of the connection posts has a flat distal surface.

A semiconductor device includes a power module, a circuit package, and a joint portion joining the power module and the circuit package. The circuit package includes a semiconductor element, a wiring layer electrically connected with the semiconductor element, a heat conductive member, and a second mold resin portion sealing the semiconductor element and the heat conductive member. The wiring layer includes a connecting portion connected with the heat conductive member. One of the connecting portion or the heat conductive member is joined with a signal wire in the power module via the joint portion. The heat conductive member penetrates the second mold resin portion in a thickness direction of the semiconductor element. The heat conductive member and the connecting portion are arranged in a straight line in the thickness direction of the semiconductor element.

A method of manufacturing a semiconductor device, includes: preparing a support substrate having a peeling layer formed on a main surface side; partially forming a wiring layer above the peeling layer; arranging a semiconductor chip on the support substrate so that a pad of the semiconductor chip is electrically connected to the wiring layer; forming an encapsulating layer that encapsulates at least a part of the wiring layer and the semiconductor chip and is in contact with the peeling layer or a layer above the peeling layer so as to form an intermediate laminated body including the semiconductor chip, the wiring layer, and the encapsulating layer on the support substrate; cutting a peripheral portion of the support substrate after forming the intermediate laminated body; and mechanically peeling the intermediate laminated body from the support substrate with the peripheral portion cut away, with the peeling layer being as a boundary.

A semiconductor device package includes a redistribution layer, a plurality of conductive pillars, a reinforcing layer and an encapsulant. The conductive pillars are in direct contact with the first redistribution layer. The reinforcing layer surrounds a lateral surface of the conductive pillars. The encapsulant encapsulates the first redistribution layer and the reinforcing layer. The conductive pillars are separated from each other by the reinforcing layer.

A chip transfer assembly and a manufacturing method therefor, a chip transfer method, and a display backplane. The chip transfer assembly comprises a transfer substrate (1); a porous adhesive layer (2) formed on the transfer substrate, first pores (21) being distributed in the porous adhesive layer; and at least one colloid protrusions (3) formed on the porous adhesive layer, the colloid protrusions having light transmittance, and second pores (31) used for accommodating luminescent conversion particles (4) being distributed in the colloid protrusions; after an LED chip (7) is transferred to a chip soldering zone, the colloid protrusions separate from the porous adhesive layer and remain on the LED chip to form a luminescent conversion layer.

Interconnecting a first chip and a second chip by a bridge member includes a chip handler for handling the first chip and the second chip. Each of the first chip and the second chip has a first surface including a first set of terminals and a second surface opposite to the first surface. The chip handler has an opening and at least one support surface for supporting the first surfaces of the first chip and the second chip when the first chip and the second chip are mounted to the chip handler. A chip support member supports the first chip and the second chip from the second surfaces, and a bridge handler is provided for inserting the bridge member through the opening of the chip handler and for placing the bridge member onto the first sets of terminals of the first chip and the second chip.

A method for fabricating a semiconductor package includes forming a release layer on a first carrier substrate. An etch stop layer is formed on the release layer. A first redistribution layer is formed on the etch stop layer and includes a plurality of first wires and a first insulation layer surrounding the plurality of first wires. A first semiconductor chip is formed on the first redistribution layer. A solder ball is formed between the first redistribution layer and the first semiconductor chip. A second carrier substrate is formed on the first semiconductor chip. The first carrier substrate, the release layer, and the etch stop layer are removed. The second carrier substrate is removed.

A package comprising a first integrated device comprising a first plurality of under bump metallization interconnects; a second integrated device comprising a second plurality of under bump metallization interconnects; a bridge coupled to the first integrated device and the second integrated device; an encapsulation layer at least partially encapsulating the first integrated device, the second integrated device, and the bridge; a metallization portion located over the first integrated device, the second integrated device, the bridge and the encapsulation layer, where the metallization portion includes at least one dielectric layer and a plurality of metallization interconnects; a first plurality of pillar interconnects coupled to the first plurality of under bump metallization interconnects, the first plurality of interconnects located in the encapsulation layer; and a second plurality of pillar interconnects coupled to the second plurality of under bump metallization interconnects, the second plurality of pillar interconnects located in the encapsulation layer.

Disclosed is a semiconductor package comprising a first redistribution substrate; a solder ball on a bottom surface of the first redistribution substrate; a second redistribution substrate; a semiconductor chip between a top surface of the first redistribution substrate and a bottom surface of the second redistribution substrate; a conductive structure electrically connecting the first redistribution substrate and the second redistribution substrate, the conductive structure laterally spaced apart from the semiconductor chip and including a first conductive structure and a second conductive structure in direct contact with a top surface of the first conductive structure; and a conductive seed pattern between the first redistribution substrate and the first conductive structure. A material of first conductive structure and a material of the second conductive structure may be different from a material of the solder ball.