A semiconductor package includes a substrate, a first semiconductor chip and a second semiconductor chip adjacent to each other on the substrate, and a plurality of bumps on lower surfaces of the first and second semiconductor chips. The first and second semiconductor chips have facing first side surfaces and second side surfaces opposite to the first side surfaces. The bumps are arranged at a higher density in first regions adjacent to the first side surfaces than in second regions adjacent to the second side surfaces.

A substrate includes a ceramic tile and a three-dimensional (3D) conductive structure. The 3D conductive structure includes a planar base layer having a bottom surface bonded to a top surface of the ceramic tile, and a block disposed above the planar base layer. The block is monolithically integrated with the planar base layer. A top surface of the block is configured as a die attach pad. The planar base layer has a base vertical thickness from the top surface of the ceramic tile to a top surface of the planar base layer. The block and the planar base layer have a combined vertical thickness from the top surface of the ceramic tile to a top surface of the block that is greater than the base vertical thickness.

A method for manufacturing a semiconductor structure includes: forming a first bonding layer on a device substrate formed with a semiconductor device so as to cover the semiconductor device, wherein the first bonding layer includes a first metal oxide material in an amorphous state; forming a second bonding layer on a carrier substrate, wherein the second bonding layer includes a second metal oxide material in an amorphous state; conducting a surface modification process on the first bonding layer and the second bonding layer; bonding the device substrate and the carrier substrate to each other through the first and second bonding layers; and annealing the first and second bonding layers so as to convert the first and second metal oxide materials from the amorphous state to a crystalline state.

This method for producing a structure wherein base materials are bonded by atomic diffusion comprises: a step for applying a liquid resin on the base material; a step for smoothing the surface of the liquid resin by surface tension; a step for forming a resin layer by curing; a step for forming a metal thin film on the resin layer; a step for forming a metal thin film on the base material; and a step for bringing the metal thin film of the base material and the metal thin film of the base material into close contact with each other, thereby bonding the metal thin film of the resin layer and the metal thin film of the base material with each other by atomic diffusion

A multiple chip package is described with multiple thermal interface materials. In one example, a package has a substrate, a first semiconductor die coupled to the substrate, a second semiconductor die coupled to the substrate, a heat spreader coupled to the die, wherein the first die has a first distance to the heat spreader and the second die has a second distance to the heat spreader, a first filled thermal interface material (TIM) between the first die and the heat spreader to mechanically and thermally couple the heat spreader to the die, and a second filled TIM between the second die and the heat spreader to mechanically and thermally couple the heat spreader to the second die.

The present disclosure provides a base plate integrating passive devices and a method for manufacturing the same, which relate to the technical field of radio frequency devices. The base plate integrating passive devices of the present disclosure includes a substrate base plate and the passive devices disposed on the substrate base plate, the passive devices including at least an inductor, the inductor including a plurality of open ring portions arranged and connected in sequence in a direction away from the base plate, wherein an interlayer dielectric layer is disposed between the open ring portions disposed adjacently, and the open ring portions disposed adjacently are electrically connected through a first via hole penetrating the interlayer dielectric layer; orthographic projections of any two of the open ring portions on the substrate base plate at least partially overlap.

The present disclosure relates to radio frequency (RF) chip packages and, more particularly, to improved thermal performance of RF chip packages and methods of manufacture. The structure includes: a board; a chip substrate; a pattern of solder bumps between the board and the chip substrate; and a thermal conductive material between the chip substrate and the board in depopulated regions of solder bumps of the chip substrate.

A semiconductor package includes: a base substrate; an interposer disposed on the base substrate, wherein the interposer includes a plurality of recesses in a bottom surface thereof; a semiconductor chip disposed on the interposer; a plurality of interposer connection terminals between the interposer and the base substrate, wherein the plurality of interposer connection terminals electrically connect the interposer to the base substrate; and a first underfill layer disposed between the interposer and the base substrate, wherein the first underfill layer at least partially surrounds the plurality of interposer connection terminals, wherein the first underfill layer at least partially surrounds a side surface of each of the plurality of recesses and has a slope declining from the bottom surface of the interposer to a top surface of the base substrate.

The semiconductor device includes first and second semiconductor elements. Each element has an obverse surface and a reverse surface, with a first electrode arranged on the reverse surface, and with a second electrode arranged on the obverse surface. The semiconductor device further includes: a first lead having an obverse surface and a reverse surface; an insulating layer covering the first lead, the first semiconductor element and the second semiconductor element; a first electrode connected to the second electrode of the first semiconductor element; and a second electrode connected to the first lead. The first semiconductor element and the first lead are bonded to each other with the reverse surface of the first semiconductor element facing the lead obverse surface. The second semiconductor element and the first lead are bonded to each other with the reverse surface of the second semiconductor element facing the lead reverse surface.

An integrated circuit package includes at least one electronic chip having a first face fastened onto a first face of a carrier substrate by an adhesive interface. The adhesive interface includes a crown formed of a first adhesive material that is fastened on the periphery of the first face of the electronic chip. The crown defining an internal housing. A second adhesive material, different than the first material, is deposited in the internal housing.