A semiconductor structure includes a substrate; a pad disposed over the substrate; a passivation disposed over the substrate and exposing a portion of the pad; and a bump disposed over the portion of the pad. The bump includes a buffering member disposed over the portion of the pad; and a conductive layer surrounding the buffering member and electrically connected to the pad.

A microelectronic substrate may be formed to have an embedded trace which includes an integral attachment structure that extends beyond a first surface of a dielectric layer of the microelectronic substrate for the attachment of a microelectronic device. In one embodiment, the embedded trace may be fabricated by forming a dummy layer, forming a recess in the dummy layer, conformally depositing surface finish in the recess, forming an embedded trace layer on the dummy layer and abutting the surface finish, and removing the dummy layer.

A semiconductor device is disclosed. The semiconductor device comprises a first die, a second die, and a redistribution structure. The first die and the second die are electrically connected to the redistribution structure. There are no solder bumps between the first die and the redistribution structure. There are no solder bumps between the second die and the redistribution structure. The first die and the second die have a shift with regard to each other from a top view.

The present application provides a semiconductor structure having a copper pillar within a solder bump, and a manufacturing method of the semiconductor structure. The semiconductor structure includes a substrate having a pad disposed thereon and a passivation at least partially surrounding the pad; and a conductive bump structure disposed over the passivation and the pad, wherein the conductive bump structure includes a first bump portion disposed over the passivation and the pad, a conductive pillar disposed over the first bump portion, and a second bump portion disposed over and surrounding the conductive pillar.

A semiconductor device includes a first conductive portion, a second conductive portion, a first layer, and a second layer. The first conductive portion includes a first end portion and a first extending portion. The first extending portion extends in a first direction. The length of the first extending portion in a second direction is shorter than a length of at least a part of the first end portion in the second direction. The first layer includes multiple semiconductor chips, multiple passive chip components, and a resin. The first extending portion includes a first portion and a second portion. The first layer is provided around the first portion. The first layer expands along a first plane. The first plane intersects the first direction. The second layer includes a first multilayer wiring. The second layer expands along a second plane intersecting the first direction.

The present application provides a semiconductor structure having a copper pillar within a solder bump, and a manufacturing method of the semiconductor structure. The semiconductor structure includes a substrate having a pad disposed thereon and a passivation at least partially surrounding the pad; and a conductive bump structure disposed over the passivation and the pad, wherein the conductive bump structure includes a first bump portion disposed over the passivation and the pad, a conductive pillar disposed over the first bump portion, and a second bump portion disposed over and surrounding the conductive pillar.

A semiconductor package includes a redistribution substrate having first and second surfaces, a first semiconductor chip on the first surface, external terminals on the second surface, a second semiconductor chip above the first semiconductor chip, external connection members below the second semiconductor chip, conductive pillars electrically connecting the external connection members to the redistribution substrate. The second semiconductor chip includes a device layer, a wiring layer, and a redistribution layer on a semiconductor substrate. The wiring layer includes intermetallic dielectric layers, wiring lines, and a conductive pad connected to an uppermost wiring line. The redistribution layer includes a first redistribution dielectric layer, a first redistribution pattern, and a second redistribution dielectric layer. A vertical distance between the semiconductor substrate and the conductive pillars is less than that between the first semiconductor chip and the external terminals.

A semiconductor device includes a substrate, a package structure, a thermal interface material (TIM) structure, and a lid structure. The package structure is disposed on the substrate. The TIM structure is disposed on the package structure. The TIM structure includes a metallic TIM layer and a non-metallic TIM layer in contact with the metallic TIM layer, and the non-metallic TIM layer surrounds the metallic TIM layer. The lid structure is disposed on the substrate and the TIM structure.

In a bonding process of a flip chip bonding method, a chip is bonded to contact pads of a substrate by composite bumps which each includes a raiser, a UBM layer and a bonding layer. Before the bonding process, the surface of the bonding layer facing toward the substrate is referred to as a surface to be bonded. During the bonding process, the surface to be bonded is boned to the contact pad and become a bonding surface on the contact pad. The bonding surface has an area greater than that of the surface to be bonded so as to reduce electrical impedance between the chip and the substrate.

A semiconductor device includes a substrate, a package structure, a thermal interface material (TIM) structure, and a lid structure. The package structure is disposed on the substrate. The TIM structure is disposed on the package structure. The TIM structure includes a metallic TIM layer and a non-metallic TIM layer in contact with the metallic TIM layer, and the non-metallic TIM layer surrounds the metallic TIM layer. The lid structure is disposed on the substrate and the TIM structure.